Energy [R]evolution 2015 by Greenpeace International

energy

[r]evolution a sustainable world energy outlook 2015

100%

renewable energy for all

report 5th edition 2015 world energy scenario

foreword The Global Energy [R]evolution series presents us with a compelling vision of what an energy future would look like for a sustainable world. The scenarios proposed by the Energy [R]evolution have in a short period of time gained a reputation for the insight and explanations they provide decision makers.

authors & reviewers

This fifth edition outlines an updated and well-articulated pathway to achieve the transition to a global sustainable energy future. The International Renewable Energy Agency (IRENA) welcomes the recognition of the central role that renewable energy will play in this new energy paradigm.

Greenpeace International,

Project manager and lead author

Research & co-authors

Global Wind Energy Council

Dr. Sven Teske, Greenpeace International

Overall Modelling: DLR, Institute of Engineering Thermodynamics, Systems Analysis and Technology Assessment, Stuttgart, Germany: Dr. Thomas Pregger, Dr. Sonja Simon, Dr. Tobias Naegler

SolarPowerEurope Date September 2015

Global Wind Energy Council Steve Sawyer SolarPowerEurope Oliver Schäfer

image SOLON AG PhOTOvOLTAIcS fAcILITy IN ARNSTEIN OPERATES 1,500 hORIzONTAL AND vERTIcAL SOLAR “MOvERS”. IT IS ThE LARGEST TRAckING SOLAR fAcILITy IN ThE wORLD, AND DELIvERS 12 MEGAwATT Of ENERGy. EAch “MOvER” cAN bE bOuGhT fROM S.A.G. SOLARSTROM AG AS A PRIvATE INvESTMENT.

Achieving this transition relies upon addressing key energy issues such as access to modern energy services, security of supply and the sustainability of the energy mix. Environmental degradation, increasing energy demand and unsustainable resource use are critical development challenges that require a coherent response. Renewable energy presents an opportunity as it will play an essential role in advancing sustainable development by providing millions with access to energy, whilst helping ensure energy security, mitigating the existential risk of climate change by reducing emissions, and generating growth and employment.

Accelerating the “Silent Revolution” globally requires greater levels of commitment and cooperation to develop enabling policy, combined with practical business solutions. To facilitate this, policy makers, scientists and businesses require access to up-to-date, relevant and reliable data. Scenarios are a helpful aid for decision making, by mapping out the complex issues and information that must be considered. Through its investigation of issues surrounding the future of energy, the Global Energy [R]evolution 2015 makes an invaluable contribution to informing decision-makers worldwide.

The benefits associated with renewables are influencing how countries meet their energy needs; the global increase in renewable energy policies and investment attests to this. This growth in the uptake of renewable energy - the “Silent Revolution” - is playing out across the globe: over the last decade 553,000 MW of renewable energy capacity has been installed, with global total investment reaching a record $ 270 billion in 2014, and the cost of modern renewable energy technologies continues to fall.

The Global Energy [R]evolution publication is an important complement to IRENA’s efforts to provide knowledge and expertise, and to facilitate the flow of information encouraging the deployment of renewables. Therefore, IRENA welcomes this fourth edition of the Global Energy [R]evolution scenario, and the contribution the Global Wind Energy Council, Solar Power Europe and Greenpeace have made to the vital debate on transitioning the world to a more secure and sustainable energy future.

Adnan Z. Amin DIRECTOR - GENERAL , INTERNATIONAL RENEWAbLE ENERGy AGENCy

SEPTEMBER 2015

Transport: DLR, Institute of vehicle concepts, Stuttgart, Germany: Dr. Stephan Schmid, Dr. Doruk Özdemir, Johannes Pagenkopf, florian kleiner

Grid and rural electrification technology: energynautics Gmbh, Langen/Germany; Dr. Thomas Ackermann, Dr. Tom brown (chapter 10)

Employment: Institute for Sustainable futures, university of Technology, Sydney: Jay Rutovitz, Elsa Dominish, Jenni Downes (chapter 6/7)

Contributing authors: Simon boxer; GP New zealand (chapter 10), Dr. Ricardo baitelo & Larissa A. Rodrigues Greenpeace brazil (chapter 6)

Editor: craig Morris, Petite Planète www.petiteplanete.org Design & Layout: Tania Dunster, Jens christiansen, onehemisphere, Sweden www.onehemisphere.se

Contact: info@greenpeace.de info@gwec.net This research has been co-financed by: umweltstiftung / Greenpeace, hongkong Strasse 10, 20457 hamburg, Germany, Melanie Stöhr umweltstiftung-greenpeace.de

foreword the energy [r]evolution project marks its first decade of ambitious (renewable) energy scenarios for countries and regions. the e[r] is now a well-known and respected projection for future renewable energy markets; it is widely seen as an alternative view to the ieaÂ´s world energy outlook.

contents at a glance

foreword introduCtion exeCutive summary chapter

2 8 10

Climate and energy PoliCy chapter

chapter

finanCing the energy

[ r ] evolution

the energy [ r ] evolution ConCePt

chapter

sCenario for a future energy suPPly

Climate Change and nuClear threats

chapter

ren21â&#x20AC;&#x2122;s renewables global status report has become over the past decade the most frequently referenced report on renewable energy market, industry and policy trends. similarly, the energy [r]evolution has provided regular projections for the current and future renewable energy markets. each edition (five to date including this one) triggers important debates within the energy sector.

image northbound and southbound shiPPing lanes off the coast of chinaâ&#x20AC;&#x2122;s shandong Peninsula.the lanes forM one of the Main routes froM the yellow sea into the bohai sea and the chinese Ports of dalian and tianJin, two of the busiest in the world. the vessels in this iMage are Most likely cargo shiPs, their ProPellers kick uP long, brown sediMent PluMes.

However, even with these successes, growth in renewables capacity as well as improvements in energy efficiency are below the rates necessary to achieve the Sustainable Energy for All (SE4All) goals of: doubling the level of renewable energy; doubling the global rate of improvement in energy efficiency; and providing universal energy access by 2030.

Renewable energy continued to grow in 2014 in parallel with global energy consumption and falling oil prices. Despite rising energy use, for the first time in 40 years, global CO 2 emissions associated with energy consumption remained stable over the course of the year while the global economy grew. The landmark “decoupling” of economic and CO 2 growth is due in large measure to China’s increased use of renewable resources, and efforts by countries in the OECD to promote renewable energy and energy efficiency. This is particularly encouraging in view of COP21 later this year in Paris, where countries will announce and/or confirm actions to mitigate climate change, setting the stage for future investment in renewables and energy efficiency.

We are still not on the pathway to 100% renewable energy globally; a lot remains to be done particularly to increase the use of renewables in the heating and transport sectors. This latest edition of the Energy [R]evolution provides insight of what needs to be done and where renewable energy markets need to go. REN21 welcomes the new Energy [R]evolution scenario as an important contribution to the global energy policy debate. It provides guidance on where investments need to reduce CO 2 emissions below the carbon budget climate scientist have identified to avoid runaway climate change.

This decoupling clearly signals that renewables have become a mainstream energy resource. The penetration and use of both variable and non-variable renewables are increasing, thereby contributing to diversification of the energy mix. As of early 2015, 164 countries have renewable energy targets in place. Many of these countries have also engaged in an energy transition path towards renewable energy and energy efficiency.

The past decade has set the wheels in motion for a global energy transition with renewables; it is accelerating in many parts of the world. With the implementation of ambitious targets and innovative policies, renewables can continue to surpass expectations and create a clean, equitable energy future.

Christine Lins ExECuTIvE SECRETARy,

REN21

chapter

sCenario results chapter

market [r]evolution

emPloyment ProjeCtions

chapter

204

seCurity of suPPly

chapter

226

energy effiCienCy

energy resourCes and

194

energy teChnologies chapter

methodology and assumPtions

the silent energy

SEPTEMBER 2015

more with less

chapter

–

transPort

286

glossary, referenCes

270

aPPendix

307

214

world energy [r]evolution a sustainable world energy outlook

ta b l e o f c o n t e n ts foreword introduction executive summary

2 8 10

chapter

climate change and nuclear threats

1.1 the imPaCts of Climate Change 1.2 Climate Change – the sCienCe 1.2.1 ObSERvED CHANGES 1.2.2 CAuSES Of CLIMATE CHANGE 1.2.3 IMPACTS Of CLIMATE CHANGE 1.2.4 ExTREME EvENTS 1.3 nuClear threats 1.3.1 NO SOLuTION TO CLIMATE PROTECTION 1.3.2 THE DANGERS Of NuCLEAR POWER

chapter

2.1

18 19 19 20 20 22 22 23 23

climate and energy policy

international Climate PoliCy

INTERNATIONAL ENERGy POLICy

2.2 renewable energy PoliCies 2.2.1 STATuS Of RENEWAbLE ENERGy POLICIES fOR 2.2.2 STATuS Of RENEWAbLE ENERGy POLICIES

ELECTRICITy

fOR HEATING AND COOLING

2.2.3 2.2.4

RENEWAbLE ENERGy TRANSPORT POLICIES

3.1 3.2 3.3 3.4

ENERGy ’ S TWIN PILLAR

the energy [ r ] evolution concept

status quo of the global energy seCtor setting uP an energy [ r ] evolution sCenario the energy [ r ] evolution logiC the

“5

chapter

steP imPlementation ”

financing the energy [ r ] evolution

4.1 4.2 4.3

renewable energy ProjeCt Planning basiCs

4.4

how to overCome investment barriers for

the imPaCts of Climate Change

renewable energy

4.5 the first deCade of renewable energy finanCing 4.5.1 INvESTMENT by ECONOMIC GROuP ( REN 21 – 2015) 4.5.2 fINANCING MODELS 4.5.3 INvESTMENT SOuRCES AS Of 2014

chapter

HEATING TECHNOLOGIES

5.4.7

ASSuMPTIONS fOR HyDROGEN AND SyNfuEL PRODuCTION fROM RENEWAbLE ELECTRICITy

5.4.8 ASSuMED GROWTH RATES IN SCENARIO DEvELOPMENT 5.4.9 ASSuMPTIONS fOR fOSSIL fuEL PHASE OuT 5.5 review: greenPeaCe sCenario ProjeCtions of the Past 5.5.1 THE DEvELOPMENT Of THE GLObAL WIND INDuSTRy 5.5.2 THE DEvELOPMENT Of THE GLObAL SOLAR

28 28

29 29 30

35 36 37 37 39

48 49 50

73 74 75 76 76 79

how does the energy [ r ] evolution sCenario ComPare to other sCenarios ?

scenario results

6.1 global sCenario results 6.1.1 GLObAL : PROjECTION Of ENERGy INTENSITy 6.1.2 fINAL ENERGy DEMAND by SECTOR 6.1.2 ELECTRICITy GENERATION 6.1.3 fuTuRE COSTS Of ELECTRICITy GENERATION 6.1.4 fuTuRE INvESTMENTS IN THE POWER SECTOR 6.1.5 ENERGy SuPPLy fOR HEATING 6.1.6 fuTuRE INvESTMENTS IN THE HEATING SECTOR 6.1.7 fuTuRE EMPLOyMENT IN THE ENERGy SECTOR 6.1.8 TRANSPORT 6.1.9 DEvELOPMENT Of CO 2 EMISSIONS 6.1.10 PRIMARy ENERGy CONSuMPTION 6.2 oeCd north ameriCa 6.3 latin ameriCa 6.4 oeCd euroPe 6.5 afriCa 6.6 middle east 6.7 eastern euroPe / eurasia 6.8 india 6.9 other asia 6.10 China 6.11 oeCd asia oCeania

83 83 84 86 87 87 88 89 89 91 92 92 94 104 114 124 134 144 154 164 174 184

chapter 7: employment projections methodology and assumptions

194

overComing barriers to finanCe and investment for renewable energy

5.1

COST PROjECTIONS fOR RENEWAbLE

chapter

DEvELOPING COuNTRIES

chapter

ENERGy TECHNOLOGIES

5.4.6

27 27 28

DISTRIbuTED RENEWAbLE ENERGy IN

2.2.6 ENERGy EffICIENCy: RENEWAbLE 2.3 PoliCy reCommendations

AND CO 2 EMISSIONS

COST PROjECTIONS fOR RENEWAbLE

5.6

CITy AND LOCAL GOvERNMENT RENEWAbLE ENERGy POLICIES

2.2.5

5.4.5

26 -

ENERGy POLICy AND MARkET REGuLATION

61 62 64 64 65 66

GENERATION AND CARbON CAPTuRE AND STORAGE

( CCS )

PHOTOvOLTAIC INDuSTRy

the unfCCC

and the kyoto ProtoCol

2.1.1

5.2 sCenario aPProaCh and baCkground studies 5.3 sCenario regions 5.4 main sCenario assumPtions 5.4.1 POPuLATION DEvELOPMENT 5.4.2 ECONOMIC GROWTH 5.4.3 OIL AND GAS PRICE PROjECTION 5.4.4 COST PROjECTIONS fOR EffICIENT fOSSIL fuEL

scenario for a future energy supply

sCenario storylines and main Premises

52 54 54 55 56 57

58 59

7.1 emPloyment faCtors 7.2 regional adjustments 7.2.1 REGIONAL jOb MuLTIPLIERS 7.2.2 LOCAL EMPLOyMENT fACTORS 7.3 emPloyment results by teChnology 7.3.1 EMPLOyMENT IN fOSSIL fuELS AND NuCLEAR TECHNOLOGy 7.3.2 EMPLOyMENT IN WIND ENERGy AND bIOMASS 7.3.3 EMPLOyMENT IN GEOTHERMAL AND WAvE POWER

196 197 197 197 199 199 200 201

energy

[r]evolution

ta b l e o f c o n t e n ts 7.3.4

continued

EMPLOyMENT IN SOLAR PHOTOvOLTAICS AND SOLAR THERMAL POWER

7.3.5

EMPLOyMENT IN THE RENEWAbLE HEATING SECTOR

chapter

the silent energy market [r]evolution

8.1 the Power Plant market 1970 to 2011 8.1.1 POWER PLANT MARkETS IN THE uS , EuROPE AND 8.2 the global market shares in the Power Plant market: renewables gaining ground 8.3 the first deCade : the develoPment of

CHINA

THE RENEWAbLE POWER SECTOR IN

the global renewable energy market in

chapter

205 207 210

2014 -

REN 21’ S ANALySIS

8.4

204

10.5.3 HvAC 10.5.4 HvDC LCC 10.5.5 HvDC vSC 10.6 renewable heating and Cooling teChnologies 10.6.1 SOLAR THERMAL TECHNOLOGIES 10.6.2 GEOTHERMAL , HyDROTHERMAL AND AERO - THERMAL ENERGy 10.6.3 HEAT PuMP TECHNOLOGy 10.6.4 bIOMASS HEATING TECHNOLOGIES 10.6.5 bIOGAS 10.6.6 STORAGE TECHNOLOGIES

2014

energy resources and security of supply

211 212

214

chapter

Pathway

for sustainable bioenergy

9.3.1 9.3.2

POLICy RECOMMENDATIONS bIOENERGy AND CLIMATE

chapter

10:

energy technologies

10.1 fossil fuel teChnologies 10.1.1 COAL COMbuSTION TECHNOLOGIES 10.1.2 GAS COMbuSTION TECHNOLOGIES 10.2 Carbon reduCtion teChnologies and Carbon CaPture and storage ( CCs ) 10.2.1 CARbON DIOxIDE STORAGE 10.2.2 CARbON STORAGE AND CLIMATE CHANGE 10.3 nuClear teChnologies 10.4 renewable Power teChnologies and heating teChnologies

10.4.1 10.4.2 10.4.3 10.4.4 10.4.5 10.4.6 10.4.7 10.4.8 10.4.9

SOLAR POWER ( PHOTOvOLTAICS ) Pv CELLS AND MODuLES Pv SySTEMS CONCENTRATING SOLAR POWER ( CSP ) CSP

THERMAL STORAGE

WIND POWER bIOMASS ENERGy bIOMASS TECHNOLOGy EMISSION REDuCTION

10.4.10 GEOTHERMAL ENERGy 10.4.11 ENHANCED GEOTHERMAL SySTEMS ( EGS ) 104.12 HyDROPOWER 10.4.13 OCEAN ENERGy 10.5 Power grid teChnologies – infrastruCture for renewables DEMAND SIDE MANAGEMENT

“ OvERLAy ”

“ SuPER

GRID ”

energy efficiency

–

262 264 266 267 267

more with less

270

demand ProjeCtions

271 271

REfERENCE DEMAND SCENARIO STEP

DEvELOPMENT Of LOW

ENERGy DEMAND SCENARIOS

11.2 energy ConsumPtion in the year 2012 11.3 referenCe demand sCenario 11.4 effiCienCy measures and Potentials 11.4.1 EffICIENCy MEASuRES IN INDuSTRy 11.4.2 EffICIENCy MEASuRES IN buILDINGS 11.5 effiCienCy Pathways of the energy [ r ] evolution 11.5.1 LOW DEMAND SCENARIO fOR INDuSTRy SECTOR 11.5.2 LOW DEMAND SCENARIO fOR buILDINGS

223 224 224

11.6

226

chapter

227 227 227

12.1

228 228 229 229

12.2.1

12:

286

transport

the future of the transPort seCtor

288

in the referenCe sCenario

12.2

TARGETS

230 232 233 233 234 237 238 241 241

teChniCal and behavioural measures to reduCe

289

244 245 246 247 249

bEHAvIOuRAL MEASuRES TO REDuCE TRANSPORT ENERGy DEMAND

12.3 ProjeCtion of the future Car market 12.3.1 PROjECTION Of THE fuTuRE TECHNOLOGy MIx 12.3.2 PROjECTION Of THE fuTuRE vEHICLE SEGMENT 12.3.3 PROjECTION Of THE fuTuRE SWITCH

304 304 306

DRIvEN PER yEAR

12.4

ConClusion

chapter

13.1 13.2

13:

glossary, references

appendix

13.6

307 308

referenCes glossary of Commonly used terms and abbreviations

13.3 13.4 13.5

289 303 303 303

PROjECTION Of THE fuTuRE kILOMETRES

list of figures and tables results data

2005 – 2015 –

311 312 316

one deCade of

energy [ r ] evolution sCenarios

254 254

SPLIT

TO ALTERNATIvE fuELS

12.3.4

271 272 274 277 277 280 282 282 283 284

AND OTHER SECTORS develoPment of energy intensities

transPort energy ConsumPtion

bIOENERGy AND GREENHOuSE GAS

( GHG )

10.5.1 10.5.2

216 216 217 218 219 219 220

11:

11.1 methodology for the energy 11.1.1 STEP 1: DEfINITION Of A 11.1.2

9.1 the energy [ r ] evolution fossil fuel 9.1.1 OIL 9.1.2 GAS 9.1.3 SHALE GAS 9.1.4 COAL 9.1.5 NuCLEAR 9.2 renewable energy 9.3 greenPeaCe PrinCiPles and Criteria

256 257 257 259 259

211

the renewable Power Plant market

8.3.1

202 203

360

overview of the energy [ r ] evolution CamPaign sinCe

2005

361

–

THE INTERCONNECTION Of SMART GRIDS

255

i n t r o d u ct i o n

image geMasolar, a 15 Mw solar Power tower Plant, sPain.

The good news first: the Energy [R]evolution is already happening! Since the first edition was published in 2005, costs for wind power and solar photovoltaics (Pv) have dropped dramatically and markets have grown substantially. between 2005 and the end of 2014 over 496,000 MW of new solar and wind power plants have been installed – equal to the total capacity of all coal and gas power plants in Europe! In addition 286,000 MW of hydro-, biomass- , concentrated solar- and geothermal power plants have been installed, totaling 783,000 MW of new renewable power generation connected to the grid in the past decade – enough to supply the current electricity demand of India and Africa combined. Renewable power generation has become mainstream in recent years. Onshore wind is already the most economic power source for new capacity in a large and growing number of markets, while solar Pv is likely to follow within the next 3 to 5 years. utilities in Europe, North America and around the globe are feeling the pressure from renewables, and the old business models are starting to erode. . In Germany, where the capacity of solar Pv and wind power is equal to peak demand, utilities like RWE and E.on struggle. More and more customers generate their own power. The future business model for utilities will have to change from selling kilowatthours to selling energy services if they are to survive. However, with all the good news from the renewable power sector, the overall transition away from fossil and nuclear fuels to renewables is far too slow to combat dangerous climate change. During the past decade almost as much capacity of new coal power plants has been installed as renewables: 750,000 MW. Over 80% of the new capacity has 8

been added in China, where not only wind and solar power lead their respective global markets, but also new coal. but there are the first positive signs that the increase in coal use is coming to an end in China. The amount of coal being burned by China has fallen for the first time this century in 2014, according to an analysis of official statistics. China’s booming coal in the last decade has been the major contributor to the fast-rising carbon emissions that drive climate change, making the first drop a significant moment. 100% renewables – a revolutionary idea gets more and more support

Phasing out nuclear and fossil fuels entirely is still a revolutionary idea and many energy experts are skeptical. However, more and more scientists, engineers and activists actively promote a 100% renewable energy vision. According to the IPCC’s latest assessment report, we have already used almost 2/3 of our carbon budget, if we are to have a reasonable chance of limiting global mean temperature rise to 2 degrees C. At the current and projected rate of consumption, this entire budget will be used by 2040. So it is essential that we move rapidly towards a new form of energy supply – one that delivers 100% renewable energy by 2050. Greenpeace and its renewable industry association partners have been researching and presenting Energy [R]evolution scenarios since 2005, and more recently has started collaborating with the scientific community. While our predictions on the potential and market growth of renewable energy may have seemed fanciful or unrealistic, they have

energy

[r]evolution

proved to be accurate. 1 The 2015 edition of the global Energy [R]evolution features: 1) a 100% renewable energy scenario for the first time; 2) a basic Energy [R]evolution case with a final energy share of 83% renewables which follows the pathway for the E[R] published in 2012; and 3) and the IEA´s World Energy Outlook 2014 Current Policies scenario extrapolated out to 2050- which serves as a reference case. the transport [r]evolution has not really started yet

While the transition towards 100% renewables in the “traditional” power and heating sector seems well within our grasp, the phase-out of fossil fuels in the transport- and parts of the industry sector are still present major challenges, especially air travel and transport. Oil dominates the global transport system and a switch from combustion engines to electric drives is not possible for example for airplans.. The “transport revolution” is not simply a technology change; it requires new mobility concepts and the auto industry need to change just like utilities, from selling a product – such as cars – to selling mobility services. Increased shares of e-mobility will increase the overall power demand significantly, adding more pressure on utilities to provide more electricity while phasing out coal and nuclear power plants. Electric mobility must go hand in hand with renewable energy expansion, as an electric car supplied by coal power plant would emit nearly as much if not more CO 2 than an efficient one with a combustion engine. new fossil fuels – a high-risk investment

The Energy [R]evolution scenario provides a pathway to phaseout the use of oil roughly at the pace of the depletion rates of existing oil fields. However, while we grapple with meeting the climate challenge, companies and governments are spending billions to develop new oil production which we cannot use. The financial community is waking up to the risks associated with not only investments in new production which may become ‘stranded assets’, but the risks to the value of the existing reserves carried by fossil fuel companies (and governments, for that matter). The bank of England2 and others have started to assess the risk to the global economy from potentially wiping trillions of dollars’ worth of ‘unburnable carbon’ assets off the balance sheets of fossil fuel companies. viewed in this context, environmentally and economically risky projects to develop new oil and gas fields in the Arctic, or in deep waters off brazil and in the Gulf of Mexico, are high stakes gambles risking not only our future but the stability of the global economy as well. While road and rail transport for people will move step by step toward electric drives, heavy duty fright will replace oil with synfuels, hydrogen or bio mass. Aviation and shipping will have to rely on fuels for the foreseeable future – and these fuels need to come from renewable energies as well. Due to strict sustainability criteria for biomass, the Energy [R]evolution scenario only uses a very limited amount which needs to be used wisely. Thus bio mass will be used mainly for aviation, references 1 2

LINk TO REPORT: HTTP://WWW.MC-GROuP.COM/THE-RENEWAbLE-ENERGy-REvOLuTION/ SEE HTTP://WWW.CARbONTRACkER.ORG/NEWS/bANk-Of-ENGLANDS-MOMENTOuS-MOvE-ON-CLIMATE-CHANGE/ AND HTTP://WWW.bLOOMbERG.COM/NEWS/ARTICLES/2014-12-18/bANkERS-SEE-1-TRILLION-Of-INvESTMENTS-STRANDED-INTHE-OIL-fIELDS

shipping (in combination with fuel saving concepts like second generation wind drives) and to provide industrial process heat. education – the fuel of the future

A 100% renewable energy supply requires changes in all sectors and it is not just a technology switch, but goes hand in hand with development of new business concepts and policies which support them. New, lighter and sustainable materials, and software development for better integrated “system thinking” requires continuous research and education. New electricity and energy market designs at both the wholesale and retail level will be required to send the right price signals. New jobs will be created while others will disappear. Investment in universities and Schools pays of better than investments in fossil fuel projects. just transition – don´t leave the workers behind

Currently there are almost 10 million workers in the global coal industry, and our calculations show that the solar photovoltaic industry could employ the same number of workers in only 15 years from now. The wind industry could grow by a factor of 10 from the current 700,000 employees to over 7 million by 2030 – twice as many as in the global oil- and gas industry today. However, this transition will have to be organized and training programs are needed to educate new workers and maintain social stability for energy workers as a whole. Even the 100% Energy [R]evolution scenario still requires 2 million coal workers in 2030 -there is a still a generation to organize the shift so no-one is left behind. but the transition must start now. barriers towards 100% renewables? the lack of consistent climate and energy policies!

A shift towards 100% renewables is possible within one generation. A baby born in 2015 can witness a fossil fuel free world by the age of 35 – but climate and energy policies globally need to pave the way away from climate chaos towards a sustainable energy supply for all. The upcoming uNfCCC climate conference in Paris needs to deliver mandatory policies for all countries. This could establish the basis of a truly sustainable energy future.

Steve Sawyer

Oliver Schäfer

SECRETARy GENERAL

PRESIDENT

GLObAL WIND ENERGy

SOLAR POWER EuROPE

COuNCIL (GWEC)

Sven Teske PROjECT LEADER ENERGy [R]EvOLuTION /GREENPEACE INTERNATIONAL SEPTEMbER 2015 9

world energy [r]evolution a sustainable world energy outlook

e x e c u t i v e s u M M a ry

image adele island, off of australia’s north coast. Made uP of a series of beach ridges built by sands washed uP froM the surrounding sandbanks during storMs. the highest Point is little More than 4 Meters (13 feet) above sea level on this grassy but treeless island. a solar-Powered lighthouse aPPears as a tiny white dot at the north tiP of the island. adele island has been classified as an iMPortant bird area because it is a breeding site of world iMPortance for lesser frigatebirds and three other sPecies.

Energy [R]evolution scenarios have become a well-known and respected energy analysis since first published in 2005. In the third version of the Energy [R]evolution published in june 2010 in berlin, we reached out to the scientific community to a much larger extent. The IPCC´s Special Report Renewables (SRREN) chose the Energy Revolution as one of the four benchmark scenarios for climate mitigation energy pathways, because it was the most ambitious scenario: combining an uptake of renewable energy and energy efficiency, it put forwards the highest renewable energy share by 2050. following the publication of the SRREN in May 2011 in Abu Dhabi, the ER became a widely quoted energy scenario and is now part of many scientific debates and referenced in numerous scientific peer-reviewed publications. In March 2015, the Energy [R]evolution received worldwide recognition when a widely circulated report from the uSbased Meister Consultants Group concluded that the rapid market growth of renewable power generation has been largely underestimated and reported that “just about no one saw it coming. The world’s biggest energy agencies, financial institutions, and fossil fuel companies, for the most part, seriously underestimated just how fast the clean power sector could and would grow”. Meister identifies one group that got the market scenario closest to right, however, and it 10

wasn’t the International Energy Agency or Goldman Sachs or the uS Department of Energy (DOE) – it was Greenpeace with the Energy [R]evolution project. The basic principles and strategic approach of the development of the Energy [R]evolution concepts have not significantly changed since the beginning. They still serve as a basis for scenario modeling. However, the methodology and underlying scientific research about transport technologies and concepts, energy resource assessments, infrastructural requirements, technology developments, and the cost of renewables have been continuously updated and improved. The renewable energy targets have been increased from 50% to 80% and finally to 100% by 2050. Since the first Energy [R]evolution was published a decade ago, the energy sector has changed significantly. Renewable energy technologies have become mainstream in most countries as a consequence of dramatically reduced costs. A future renewable energy supply is no longer science fiction, but work in progress. However, the growth rates of renewables – especially in the heating sector and in transport – are far too slow to achieve the energy-related CO2 reductions required to avoid dangerous climate change. A fundamental shift in the way we consume and generate energy must begin immediately and be well

energy

[r]evolution

underway before 2020 in order to avert the worst impacts of climate change. 1 We need to limit global warming to less than 2° Celsius, above which the impacts become devastating. climate change is not a prediction anymore – it is reality

the on-going energy revolution is still far too slow

The International Energy Agency published an evaluation of the current development of the energy sector in May 2015 (IEA – TCEP 2015),2 which concluded that the implementation of renewables and energy efficiency is successful but too slow to meet the 2°C target. Here are some of the IEA’s conclusions:

The world’s energy supply has bestowed great benefits on society, but it has also come with high price tag. The world’s most rigorous scientific bodies are in agreement on climate change, which is occurring due to a build-up of greenhouse gases, especially carbon dioxide, in the atmosphere caused by human activity.

costs : Increasingly, renewables are competitive with new

Globally, most fossil fuel is used to generate energy, either electricity, heat, or motor fuel. We have evidence that, if unchanged, the growth of fossil energy will lead to unmanageable impacts on the global population.

variable, distributed renewables. Obstacles still exist for the financing of renewable energy projects and grid connections, thereby slowing down the transition. but the worst policy mistakes are uncertainty and retroactive changes.

Climate change threatens all continents, living systems, coastal cities, food systems and natural systems. It will mean more natural disasters like fire and floods, disruption to food growing patterns and damage to property as sea levels rise.

technology : Cogeneration and renewable heat have both

If we remain dependent on fossil fuel in the pursuit of energy security, the result will be a potentially catastrophic spiral towards increasing greenhouse gas emissions and more extreme climate impacts. The need for more fuels is driving the industry towards unconventional sources, like shale oil and gas, and gigantic coal mines, which destroy ecosystems and put water supply in danger. Relying on a fuel that has a fluctuating cost on the global market is also harmful to economies. The use of nuclear energy is sometimes touted as a climate change solution, but it is simply not viable. Apart from being too dangerous and too slow to develop, it is also incredibly expensive if all economic costs over plant lifetime are taken into account. furthermore, by switching to unconventional sources, we extract more carbon from the ground. yet, since the International Energy Agency coined the term “un-burnable carbon,” the consensus is that we must leave most (around two thirds) of our current carbon resources in the ground if the world is to stay within its carbon budget. The more unconventional fuels we add to our resources, the less likely staying within an increase of two degrees Celsius becomes. According to the IPCC identified the remaining carbon budget: humankind cannot emit more than 1,000 gigatonnes of CO2 from now. Therefore it is essential to move rapidly towards a decarbonized energy system – in ideal case one that delivers 100% renewable energy by 2050.

references 1 2

IPCC – SPECIAL REPORT RENEWAbLES, CHAPTER 1, MAy 2011. (IEA – TCEP 2015) TRACkING CLEAN -ENERGy PROGRESS 2015; ENERGy TECHNOLOGy PERSPECTIvES 2015 ExCERPT; IEA INPuT TO THE CLEAN ENERGy MINISTERIAL; INTERNATIONAL ENERGy AGENCy; 9 RuE DE LA féDéRATION; 75739 PARIS CEDEx 15, fRANCE; WWW.IEA.ORG. (REN21-2015); RENEWAbLES 2015 GLObAL STATuS REPORT, PARIS: REN21 SECRETARIAT; WWW.REN21.NET; ISbN 978-39815934-6-4

fossil fuel plants, and the cost gap between renewable electricity and fossil power from new plants is closing worldwide. Nonetheless, markets still do not reflect the true environmental cost of power generation from fossil fuels. policy : Power markets must be redesigned to accommodate

grown in absolute terms but are not increasing quickly enough as a share of energy supply. The share of cogeneration in power supply has even stagnated. Likewise, battery storage has mainly been developed for mobility up to now but is increasingly used for frequency regulation to integrate a greater share of variable renewables. mobility : Electric vehicles are catching on, with an increasing number of manufacturers now offering hybrid and electric options. fuel efficiency standards have also made light vehicles more efficient. The standard should now be applied to larger trucks and buses. buildings : The technologies are available, and targets are in

place in many regions. However, the rate and depth of energy-efficient renovations needs to increase for true progress to be made in this sector because the building stock has a service life counted in decades. The Renewable Policy Network for the 21st Century (REN21) has undertaken a global renewable market analysis each year in june since 2004. The publication – “Renewables – Global Status Report” – is among the most comprehensive global and national surveys of the renewable industry sector. According to the latest edition, the global renewable energy market in 2014 was dominated by three power generation technologies: solar photovoltaics (Pv), wind, and hydro. Combined, these technologies added 127 GW of new power generation capacity worldwide. by year’s end, renewables made up an estimated 60% of net additions to the global power capacity. In several countries renewables represented a higher share of added capacity (REN21-2015). 3 The increase in market volume and strong global competition led to significant cost reductions, especially for solar Pv and wind power. As a result, other renewable energy technologies were under pressure to lower costs, particularly in the heating sector due to the increased competitiveness of electricity-based heating systems. Costcompetitive solar Pv in combination with electrical heat pumps have become economically viable, negatively impacting the solar thermal collector market. 11

world energy [r]evolution a sustainable world energy outlook

While developments in the renewable energy, heating and cooling sector were slower than in the power sector, the markets for solar thermal collectors and geothermal heat pumps grew by 9%. bio-heat production remained stable in 2014, increasing only 1% from 2013 levels. The lack of infrastructure for heating systems and an uncertain policy environment impeded the development of the renewable energy renewable energy heating market (REN21-2015).

biofuels and only 1% from electricity (IEA WEO SR 2015). A transition from fossil fuels to renewable electricity – either directly or via synthetic fuels – for the entire global transport sector is required in order to phase-out carbon emissions. This is one of the most difficult parts of the Energy [R]evolution and requires a true technical revolution. It is ambitious but nevertheless possible with currently available technologies for land-based and other transport.

The number of electric vehicles worldwide doubled year over year to 665,000. E-mobility and recent developments in battery storage (including significant cost reductions) are likely to change the future role of renewable energy in the transport sector. biofuels, however, are still the main renewable fuel source in the transport sector; they grew by 8.4% in 2014 compared the previous year (REN21-2015).

14% of all fossil transport fuels are used for “bunker fuel,” meaning transport energy for international shipping and international air transport. In order to replace bunker fuels entirely with renewables, a combination of energy efficiency and renewable fuels is required. both the marine and aviation sector can start this transition, but we need more research and development along the way towards a truly 100% renewable system. biofuels and synfuels – produced with renewable electricity – are the only realistic renewable energy option for planes currently and for the next decade. for ships, new wind-based drives, such as new generation sails and flettner rotors, are needed to replace some engine fuels.

In conclusion, developments in the heating/cooling sector and the transport sector in particular are far too slow. Despite all the success in the renewable power sector, the extreme growth of coal power generation, especially in China, undercuts many successes with renewables. However, the first sign of a stagnation of coal demand in China – even a small decline for the first time in 2014 – provides reason to hope. The political framework of energy markets must adapt to the newly emerging, mostly distributed energy technologies in order to support the transition to 100% renewable energy supply. Thus, Energy [R]evolution has begun, especially in the power sector, but heating and transport significantly lag behind. Overall, the transition from fossil and nuclear fuels to renewables is too slow, and energy demand is still growing too quickly. less is more

using energy efficiently is cheaper than producing new energy from scratch and often has many other benefits. An efficient clothes washing machine or dishwasher, for example, uses less power and saves water, too. Efficiency in buildings doesn’t mean going without – it should provide a higher level of comfort. for example, a well-insulated house will feel warmer in the winter, cooler in the summer and be healthier to live in. An efficient refrigerator is quieter, has no frost inside or condensation outside, and will probably last longer. Efficient lighting offers more light where you need it. Efficiency is thus really better described as ‘more with less’. the transport revolution must start in megacities

Sustainable transport is needed just as much as a shift to renewable electricity and heat production in order to reduce the level of greenhouse gases in the atmosphere. Today, just over one fourth (27%) (IEA WEO SR 2015) of current energy use comes from the transport sector, including road and rail, aviation and sea transport. by the end of 2013, 92.7% of all transport energy need came from oil products, 2.5% from 12

The transport [R]evolution, however, must start in (mega)cities, where a modular shift from individual to efficient and convenient public transport systems powered by renewable electricity is possible in a short time frame and with currently available technologies. Political action is the main barrier in changing land-based transport systems. the global energy [r]evolution – key results

Renewable energy sources accounted for primary energy demand in 2012. The main are biomass and hydro, which are mostly and transport but increasingly in the power

12% the world´s sources of today used for heating sector as well.

for electricity generation, renewables contribute about 21%, just as for heat supply (21%). While solar photovoltaic and wind revolutionize the power sector with increasing shares, hydropower remains the largest renewable source. biomass is the number one source for renewable heating. However, geothermal heat pumps and solar thermal collectors increasingly contribute as well. About 81.2% of the primary energy supply today still comes from fossil fuels energy. The two Energy [R]evolution scenarios describe development pathways to a sustainable energy supply, achieving the urgently needed CO 2 reduction target and a nuclear phaseout, without unconventional oil resources. The key results of the global Energy [R]evolution scenarios are the following: • use energy wisely: Combining the projections on population development, GDP growth and energy intensity results in future development pathways for the world’s final energy demand. under the Reference scenario, total final energy demand increases by 65% from the current 326,900 Pj/a to 539,000 Pj/a in 2050. In the basic Energy [R]evolution scenario, final energy demand decreases by 12% compared to current consumption and is expected to reach

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289,000 Pj/a by 2050. The Advanced scenario will shift the energy demand trends; the peak will be reached in 2020 with a total consumption of 355,000 Pj/a – 7% below the Reference case - and remain at that level for about a decade. Due to a faster electrification of the transport sector including higher shares of public transport the overall final energy demand drops below current levels before 2040 and reaches 279,000 Pj/a by 2050 – 15% below the current global demand. • electricity replaces fuels: under both Energy [R]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors. Total electricity demand will rise from about 18,860 TWh/a in 2012 to 37,000 TWh/a by 2050 in the basic Energy [R]evolution scenario. Compared to the Reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 16,700 TWh/a. This reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. The transformation to a carbon free 100% renewable energy system in the Advanced Energy [R]evolution scenario will further increase the electricity demand in 2050 up to more than 40,000 TWh/a. Electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. Around 8,100 TWh are used in 2050 for electric vehicles and rail transport, around 5,100 TWh for hydrogen and 3,600 TWh for synthetic liquid fuel generation for the transport sector (excluding bunkers). • reducing global heat demand: Efficiency gains in the heating sector are even larger than in the electricity sector. under both Energy [R]evolution scenarios, consumption equivalent to about 76,000 Pj/a is avoided through efficiency gains by 2050 compared to the Reference scenario. As a result of energy-related renovation of the existing stock of residential buildings, the introduction of low energy standards and ‘passive climatisation’ for new buildings, as well as highly efficient air conditioning systems, enjoyment of even greater comfort and better energy services will be accompanied with much lower future energy demand. • electricity generation: The development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. This trend will more than compensate for the phasing out of nuclear power production in the Energy [R]evolution scenarios, continuously reducing the number of fossil fuel-fired power plants as well. by 2050, 92% of the electricity produced worldwide will come from renewable energy sources in the basic Energy [R]evolution scenario. ‘New’ renewables – mainly wind, Pv, CSP and

geothermal energy – will contribute 68% to the total electricity generation. Already by 2020, the share of renewable electricity production will be 31% and 58% by 2030. The installed capacity of renewables will reach about 7,800 GW in 2030 and 17,000 GW by 2050. A 100% electricity supply from renewable energy resources in the Advanced scenario leads to around 23,600 GW installed generation capacity in 2050. by 2020, wind and Pv will become the main contributors to the growing market share. After 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. The Energy [R]evolution scenarios will lead to a high share of flexible power generation sources (Pv, wind and ocean) of already 31% to 36% by 2030 and 53% to 55% by 2050. Therefore, smart grids, demand side management (DSM), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity. • future costs of electricity generation: The introduction of renewable technologies under both Energy [R]evolution scenarios slightly increases the future costs of electricity generation compared to the Reference scenario by 2030. However, this difference in full cost of generation will be minor with around 0.2 uS$ cent/kWh in both the basic E[R] and the 100% renewables Advanced scenario, however, without taking into account potential integration costs for storage or other load-balancing measures. Due to increasing prices for conventional fuels, electricity generation costs will become economically favourable across all world regions starting in 2030 under the Energy [R]evolution scenarios. In some countries such as China and India, the Energy [R]evolution pathway – under the assumption of global fuel price paths – is economical from the very beginning and cheaper than conventional power supply after 2020 already. by 2050, the average global generation costs in the basic Energy [R]evolution will be 2.5 uS$ cent/kWh below the Reference case, while the Advanced scenario achieves lower cost savings due to higher capacity needs (1.7 uS$ cents/kWh below the Reference case). • the future electricity bill: under the Reference scenario, on the other hand, growth in demand and increasing fossil fuel prices result in total electricity supply costs rising from today’s uS$ 2.06 trillion per year to more than uS$ 5.35 trillion in 2050, compared to 19% lower costs (uS$ 4.3 trillion) in the basic E[R] scenario due to increasing energy efficiency and shifting energy supply to renewables. The Advanced scenario with 100% renewable power replaces more fossil fuels with electricity and therefore leads to higher overall generation costs of uS$ 6.2 trillion by 2050 but savings in fuel supply costs especially for the transport and industry sector due to a fossil fuel phase-out. both Energy [R]evolution scenarios not only comply with 13

world energy [r]evolution a sustainable world energy outlook

world´s CO 2 reduction targets, but also help stabilise energy costs and relieve the economic pressure on society. • world: future investments in the power sector: Around uS$ 48 trillion is required in investment for the Energy [R]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately uS$ 1.23 trillion per year, about 50% more than in the Reference case (uS$ 24.5 trillion or 0.63 trillion per year). Investments for the Advanced scenario add up to uS$ 64.6 trillion by 2050, on average uS$ 1.66 trillion per year, including high investments in additional power plants for the production of synthetic fuels. under the Reference scenario, the level of investment in conventional power plants adds up to almost 50%, while the other half would be invested in renewable energy and cogeneration by 2050. under both Energy [R]evolution scenarios, however, around 95% of the entire investment in the power sector would shift towards renewables and cogeneration. by 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants. because renewable energy has no fuel costs, the fuel cost savings in the basic Energy [R]evolution scenario reach a total of uS$ 39 trillion by 2050, approximately uS$ 1 trillion per year. The total fuel cost savings would therefore cover 170% of the total additional investments compared to the Reference scenario. fuel cost savings in the Advanced scenario are even higher and add up to uS$ 42 trillion, or uS$ 1.1 trillion per year. Thus additional investment under the Advanced scenario would be covered entirely (107%) by fuel cost savings. Renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas would continue to be a burden on national economies. • world: energy supply for heating: Today, renewables meet around 21% of the global energy demand for heating, the main contribution coming from the use of biomass. Dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. In Energy [R]evolution scenarios, renewables provide 42% (basic) and 43% (advanced) of global heat demand in 2030 and 86% / 94% in 2050 respectively.

◦ Energy efficiency measures help to reduce the currently growing energy demand for heating by 33 % in 2050 (relative to the Reference scenario), in spite of improving living standards and economic growth.

◦ In the industry sector solar collectors, geothermal energy (incl. heat pumps) as well as electricity and hydrogen from renewable sources are increasingly substituting for fossil fuel-fired systems.

◦ A shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of CO2 emissions. up to 2030, biomass remains the main contributor of the growing market share. After 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will further reduce the dependence on fossil fuels. The Advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity. • world: future investments in the heating sector: In the heating sector, the Energy [R]evolution scenarios also require a major revision of current investment strategies in heating technologies. In particular, far more solar thermal, geothermal and heat pump technologies need to be installed if these potentials are to be tapped for the heating sector. The use of biomass for heating purposes - often traditional biomass today - will be substantially reduced in the Energy [R]evolution scenarios and replaced by more efficient and sustainable renewable heating technologies. Renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar arrays. Thus, it can only be roughly estimated that the Energy [R]evolution scenario in total requires around uS$ 16.3 trillion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) approximately uS$ 420 billion per year. The Advanced scenario assumes an even more ambitious expansion of renewable technologies resulting in an average investment of around uS$ 429 billion per year, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with hydrogen or other synthetic fuels. • world: future employment in the energy sector – reference versus advanced scenario: The Advanced Energy [R]evolution scenario results in more energy sector jobs globally at every stage of the projection. ◦ There are 35.5 million energy sector jobs in the Advanced Energy [R]evolution in 2020, and 29.6 million in the Reference scenario. ◦ In 2025, there are 45.2 million jobs in the Advanced Energy [R]evolution scenario, and 29.1 million in the Reference scenario.

◦ In 2030, there are 46.1 million jobs in the Advanced Energy [R]evolution scenario and 27.3 million in the Reference scenario. jobs in the coal sector decline in both the Reference scenario and the Advanced scenario, as a result of productivity improvements in the industry, coupled with a move away from coal in the Advanced Energy [R]evolution scenario.

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In the Reference scenario jobs increase slightly to 2020, after which energy sector jobs decline. This is mainly driven by losses in the coal sector. At 2030, jobs are 4% (2.3 million) below 2015 levels. In the Energy [R]evolution scenario, strong growth in the renewable sector leads to an increase of 25% in total energy sector jobs by 2020, and job numbers are nearly 60% above 2015 levels in 2025. job numbers continue to rise after 2025, to reach 46.1 million jobs by 2030. Renewable energy accounts for 86% of energy jobs by 2030. Solar photovoltaics will provide 9.7 million jobs, equal to the amount of coal jobs today. Employment in the wind sector will increase by a factor of 10 from 0.7 million today to over 7.8 million in 2030, twice as many jobs as the current oil and gas industry. • world: transport: A key target is to introduce incentives for people to drive smaller cars and use new, more efficient vehicle concepts. In addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the expanding large metropolitan areas. Along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the Reference scenario. Due to population increase, GDP growth and higher living standards, energy demand from the transport sector is expected to increase in the Reference scenario by around 65% from 90,000 Pj/a in 2012 to 148,000 Pj/a in 2050. In the basic Energy [R]evolution scenario, efficiency measures and modal shifts will save 53% (78,700 Pj/a) in 2050 compared to the Reference scenario. Additional modal shifts and technology switches lead to even higher energy savings in the Advanced scenario of 62% (92,000 Pj/a) in 2050 compared to the Reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. by 2030, electricity will provide 9% of the transport sector’s total energy demand in the Energy [R]evolution, while in 2050 the share will be 39% in the basic and 52% in the Advanced scenario. Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. In 2050, up to 14,000 Pj/a of hydrogen is used in the transport sector for the Advanced Energy [R]evolution scenario. • world: development of CO2 emissions: While the world’s emissions of CO 2 will increase by 56% between 2012 and 2050 under the Reference scenario, under the basic Energy [R]evolution scenario they will decrease from 30,470 million tonnes in 2012 to 4,360 million tonnes in 2050. Annual per capita emissions will drop from 4.3 tonne to 0.5 tonne. In spite of the abstinence of nuclear power production and increasing power demand, CO2 emissions will decrease in the electricity sector. In the long run, efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well.

With a 31% share of CO2, the industry sector will be the largest source of emissions in 2050 in the basic E[R] scenario. by 2050, global CO 2 emissions are around 80% below 1990 levels in the basic Energy [R]evolution scenario. co 2 emission peak by 2020: The 100% renewable energy Advanced Energy [R]evolution scenario will decarbonize the entire energy system by 2050. under that pathway the combination of energy efficiency and renewable energy technologies will lead to a stabilization of global CO 2 emissions by 2020 and a constant reduction towards near zero emissions in 2050. by 2030, global CO 2 emissions would be back to 1990 levels. Only a decade later, a further 60% reduction is achieved. The total carbon emission between 2012 and 2050 would add up to 667 Gt CO 2 in the Advanced Energy [R]evolution scenario and 744 Gt CO 2 in the basic E[R]. In comparison, the Reference would lead to 1,400 Gt CO 2 between 2012 and 2050 – more than twice as much as under the Advanced scenario bringing the world to a +4°C pathway with disastrous consequences for the global flora and fauna and life-threatening impacts for the humanity. Switching to 100% renewable is therefore a matter of survival. • world: primary energy consumption: under the basic E[R] scenario, primary energy demand will decrease by 19% from today’s 534,870 Pj/a to around 433,000 Pj/a. Compared to the Reference scenario, overall primary energy demand will be reduced by 50% in 2050 under the E[R] scenario (REf: around 860,000 Pj in 2050). The Advanced scenario results in a slightly primary energy consumption of around 450,000 Pj in 2050 due to additional conversion losses for the production of synthetic-fuels. The Energy [R]evolution scenario aims to phase out coal and oil as fast as technically and economically possible by expanding renewable energy and quickly rolling out very efficient vehicle concepts in the transport sector to replace oil-powered combustion engines. This leads to an overall renewable final energy share of 42% in 2030 and 72% in 2040 in the Advanced E[R]. by 2050, 100% of all global energy demand is covered with renewables. The only remaining fossil fuels are assumed for non-energy uses, such as petrochemical and steel products. further research is needed

further research and development of innovative technologies is a precondition of the Energy [R]evolution and the required fundamental transformation of the energy systems. Thus, the scenarios assume further improvements of performance and costs of plants for electricity and heat generation from renewables, new vehicle concepts and in an implicit way also for other infrastructures such as electricity and heating grids, charging infrastructure, synthetic fuel generation plants or 15

world energy [r]evolution a sustainable world energy outlook

storages and other load balancing options. The spatial resolution of the scenarios and their development pathways is very coarse distinguishing ten different world regions. Energy systems and aspects such as the refinancing of investment in new capacities are largely determined by specific local and regional conditions. Therefore, the Energy [R]evolution needs more in-depth systems analysis and assessment of alternative pathways and concepts under different framework conditions such as potentials and costeffectiveness of renewable energy use. Infrastructural needs, economic and societal aspects need to be considered at least country-wise and by more sophisticated methods as it was possible for this study. Such analyses are already done or underway in several countries and regions. Other countries and regions still need more scientific analysis of feasible ways deploying their potentials for efficiency measures and renewable energies and for implementing new technologies in a cost-effective way. To fully understand the Energy [R]evolution requires the use and further development of existing sophisticated modelling approaches such as system dynamics, agent-based modelling of actor’s behaviour or dynamic modelling of capacity expansion and operation with high spatial and temporal resolution. policies required for a transition to 100% energy [r]evolution:

To make the Energy [R]evolution a reality, immediate political action is required. There are no economic or technical barriers to move to 100% renewable energy in the long-term. Governments regulate energy markets, both for supply and demand; they can educate everyone from consumers to industrialists and stimulate the markets for renewable energy and energy efficiency by implementing a wide range of economic mechanisms. They can also build on the successful policies already adopted by other countries. To get started, governments need to agree on further binding emission reduction commitments under the uNfCCC process. Meanwhile, the global emissions landscape is changing rapidly. As a result of declining coal consumption in China, global energy-related CO 2 emissions remained stable in 2014 for the first time in 40 years, despite continued economic growth. If global mitigation endeavours are strengthened, this trend will continue. This new landscape provides a greater chance that the coal, oil and nuclear industries – which continue to fight to maintain their dominance by propagating the outdated notion that citizens need their unsustainable energy – will face dramatic changes in both energy markets and support from governments. an effective climate agreement should include strong short-

term action and set out a clear long-term pathway. key elements include the following:

a strong long-term goal: phase-out of fossil fuels and nuclear power by 2050 through a just transition towards 100% renewable energy, as well as the protection and restoration of forests . A

clear signal to decision-makers and investors at all levels that the world is moving towards phasing out carbon emissions entirely and accelerating the transition to 100% renewable energy is needed. Countries’ short-term emission reduction commitments must align with this long-term goal and support transformational change, ensuring both fairness and solidarity. a 5-year cycle process for country commitments starting in 2020. All countries’ commitments should follow a 5-year

commitment period starting in 2020, which would form the first period of the Paris Protocol. Moving forward, each period would further deepen the commitments, allowing no backsliding. 5-year commitment periods incentivize early action, allow for dynamic political responses and prevent the lock-in of low ambition. They allow for a timely adaptation to the technological advances of renewable energies and energy efficiency. legally binding : A legally binding protocol - including common

accounting rules for mitigation and finance - will compel leaders to act boldly; legally binding obligations are a real expression of political will, ensuring durability in the face of political changes and increased ambition over time. shifting subsidies away from fossil fuels : All countries should commit to phase-out all subsidies - both for production and consumption - for fossil fuels by 2020. strong commitment for adaptation, finance and loss and damage : The Paris Protocol should acknowledge that less

mitigation action means a greater need for adaptation, especially finance. Consequently, an adaptation goal should be established to ensure that the level of support meets vulnerable countries’ needs under the actual warming anticipated. A roadmap must be adopted in Paris to meet the uS$ 100 billion commitment for climate financing by 2020. bring down emissions before 2020. The gap between the

agreed upon goal of keeping warming below 2°C/1.5°C and what countries actually intend to do by 2020 is widely acknowledged. The pledges at the time of this writing (mid2015) would lead us into a world of 3 or more degrees warming, with all its devastating consequences for humans and ecosystems. While a process on how to bring the emissions down was established at COP17 in 2011, countries are still – four years later – failing to agree upon sufficient action to mitigate greenhouse gases. In Paris at the latest, governments and corporate leaders need to provide innovate solutions for breaking the stalemate and laying the groundwork for bold actions before 2020.

c l i M at e c h a n g e a n d n u c l e a r t h r e ats climate change – the science

nuclear threats no solution to cliMate Protection

the dangers of nuclear Power

“

bridging the carbon gap”

the impacts of climate change

image the region of bohai sea, yellow sea, and east china is one of the Most turbid and dynaMic ocean areas in the world. the brown area along china’s subei shoal is turbid water coMMonly seen in coastal regions. shallow water dePths, tidal currents, and strong winter winds likely contributed to the Mixing of sediMent through the water.

world energy [r]evolution a sustainable world energy outlook

The world’s power supply has bestowed great benefits on society, but it has also come with high price tag. The world’s most rigorous scientific bodies are in agreement on climate change, which is occurring due to a build of greenhouse gases, especially carbon dioxide, in the atmosphere caused by human activity. Globally, most fossil fuel is used to generate energy, either electricity, heat, or motor fuel. We have evidence that, if unchanged, the growth of fossil energy will lead to unmanageable impacts on the global population. Climate change threatens all continents, living systems, coastal cities, food systems and natural systems. It will mean more natural disasters like fire and flood, disruption to food growing patterns and damage to property as sea levels rise. If we remain dependent on fossil fuel in the pursuit of energy security, the result will be a potentially catastrophic spiral towards increasing greenhouse gas emissions and more extreme climate impacts. The need for more fuels is driving the industry towards unconventional sources, like shale oil and gas, and gigantic coal mines, which destroy ecosystems and put water supply in danger. Relying on a fuel that has a fluctuating cost on the global market is also harmful to economies. furthermore, by switching to unconventional sources, we extract more carbon from the ground. yet, since the International Energy Agency coined the term “un-burnable carbon,” the consensus is that we must leave most (around two thirds) of our current carbon resources in the ground if the world is to stay within its carbon budget. The more unconventional fuels we add to our resources, the less likely staying within an increase of two degrees Celsius becomes. The use of nuclear energy as a climate change solution is sometimes touted as a solution, but it is simply not viable. Apart from being too dangerous and too slow to develop, it is also incredibly expensive.

1.1 the impacts of climate change Every day, we damage our climate by using fossil fuels (oil, coal and gas) for energy and transport. The resulting changes are likely to destroy the livelihoods of millions of people, especially in the developing world, as well as ecosystems and species, over the coming decades. Significantly reducing our greenhouse gas emissions makes both environmental and economic sense.

box 1.1 | what is the greenhouse effect?

The greenhouse effect is a natural process, in which the atmosphere traps some of the sun’s energy, warming the earth and moderating our climate. Increase in ‘greenhouse gases’ from human activity has enhanced this effect, artificially raising global temperatures and disrupting our climate. The main greenhouse gas is carbon dioxide produced by burning fossil fuels and through deforestation. Others include methane from agriculture, animals and landfill sites; nitrous oxide from agricultural production; and a variety of industrial chemicals.

According to the Intergovernmental Panel on Climate Change, the united Nations forum for established scientific opinion, the world’s temperature is expected to increase over the next hundred years by up to 4.8° Celsius if no action is taken to reduce greenhouse gas emissions – much faster than anything experienced so far in human history. At more than a 2°C rise, damage to ecosystems and disruption of the climate system increase dramatically. An average global warming of more than 2°C threatens millions of people with an increased risk of hunger, disease, flooding and water shortages. A certain amount of climate change is now “locked in”, based on the amount of carbon dioxide and other greenhouse gases already emitted into the atmosphere since industrialisation. No one knows exactly how much warming is “safe” for life on the plant. However, we know is that the effects of climate change are already impacting populations and ecosystems. We can already see melting glaciers, disintegrating polar ice, thawing permafrost, dying coral reefs, rising sea levels, changing ecosystems, record droughts, and fatal heat waves made more severe by a changed climate. 1.2 climate change – the science En November 2014, the 5th Assessment Report of the International Panel on climate change (IPCC) was published. Over 5 years, several hundered climate scientists analysed the latest scientific literature to pull together a comprehensive overview about the latest finds of climate research. This subchapter summarizes the key findings based on the Summary for Policy Makers (SPM).

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1.2.1 observed changes

first, the IPCC sees a clear human component in climate change, with anthropogenic greenhouse gas emissions having reached an unprecedented level. The result will be considerable detrimental impacts on “human and natural systems” (IPCC-AR 5 SPM). 1 There is no question that global warming is happening; indeed, “since the 1950s, many of the observed changes are unprecedented over decades to millennia. The atmosphere and ocean have warmed, the amounts of snow and ice have diminished, and sea level has risen.” (IPCC-AR 5 SPM). The global average temperature per decade at the earth’s surface continues to increase, with 1983 to 2012 likely being “the warmest 30-year period of the last 1400 years in the Northern Hemisphere.” from 1880 to 2012, the planet has warmed up by 0.85 degrees Celsius. (IPCC-AR5-SPM) Global warming affects the planetary water cycle. Areas with little precipitation have waters of higher salinity because more water is lost through evaporation than precipitation. Globally, these areas are indeed becoming more saline, whereas waters have become fresher in areas of greater precipitation since the 1950s – a clear sign that dry areas are becoming drier while wet areas are getting wetter.

figure 1.2 | globaly averaged sea level change

source IPCC-AR5-SPM.

figure 1.3 | globaly averaged greenhouse gas concentrations

Likewise, the oceans have absorbed more CO 2 since the beginning of industrialization. As a result, ocean surface water has become 26 percent more acidic, with the pH having decreased by 0.1 (IPCC-AR5-SPM).

source IPCC-AR5-SPM.

figure 1.1 | globaly averaged combined land and ocean surface temperature anomaly

figure 1.4 | globaly anthropogenic co 2 emissions

source IPCC-AR5-SPM.

references 1

(IPCC-AR5-SPM) INTERNATIONAL PANEL ON CLIMATE CHANGE – 5TH ASSESSMENT REPORT; CLIMATE CHANGE 2014, SuMMARy fOTR POLICy MAkERS; HTTP://IPCC.CH/PDf/ASSESSMENT-REPORT/AR5/SyR/AR5_SyR_fINAL_SPM.PDf

world energy [r]evolution a sustainable world energy outlook

from 1992 to 2011, the world’s largest ice sheets – in Greenland and the Antarctic – also shrank dramatically, and glaciers are melting almost everywhere. Scientists are also highly confident that temperatures in most permafrost regions have increased since the early 1980s, partly due to changing snow cover (IPCC-AR5-SPM). Likewise, Arctic sea ice shrank by 3.5 to 4.1 percent per decade from 1979 to 2012. In contrast, the extent of Antarctic sea ice increased by 1.2 to 1.8 percent per decade from 1979 to 2012 as more ice slipped from the continent into the water (IPCC-AR5-SPM). As more ice melts, sea level rises. According to the IPCC, “Over the period 1901 to 2010, global mean sea level rose by 0.19 m on average,” faster than at any time in the past 2000 years (IPCC-AR5-SPM). 1.2.2 causes of climate change

The atmosphere lets light pass through to the surface, where objects absorb this energy, giving off heat radiation in the process. The atmosphere then partially traps this heat. Since the beginning of industrialization, anthropogenic greenhouse gases (GHGs) have significantly increased concentrations of carbon dioxide ( CO 2), methane (CH4) and nitrous oxide (N2O), to name the three most potent GHGs (IPCC-AR5-SPM). As a result, Earth’s atmosphere is more effective at trapping heat. Population growth is a major factor in carbon emissions from fossil fuel consumption, but the impact of this growth remained stable from 2000 to 2010 relative to the three previous decades. In contrast, the impact of economic growth has skyrocketed. In particular, greater coal consumption has begun to make the global carbon intensity of energy consumption higher once again after a brief period of progress (IPCC-AR5-SPM). Since the IPCC’s fourth Assessment Report, scientists have collected even more evidence of man-made climate change. In fact, scientists now estimate that anthropomorphic impacts make up “more than half of the observed increase in global average surface temperature from 1951 to 2010” (IPCC-AR5-SPM). All continents except Antarctica are affected. Since 1960, anthropomorphic effects are likely to have affected the global water cycle, including the melting of glaciers and, since 1993, surface melting of the Greenland ice sheet. Likewise, civilization’s emissions are very likely contributors to Arctic sea ice loss since 1979 and the global mean sea level rise observed since the 1970s. 1.2.3 impacts of climate change

Natural and human systems are sensitive to climate change, and impacts have been observed on all continents and in oceans (IPCC-AR5-SPM). Along with melting snow and ice, changes in precipitation are affecting both the quantity and quality of water resources. On land and in both fresh and saltwater, numerous species – plant and animal – have seen the location of their habitats shift, as have migration patterns. 20

Seasonal activities are also changing, and species are interacting differently in response to climate change. Ocean acidification also affects marine life. you don’t need to be a scientist to measure the changes. Humans are also witnessing the effects directly, with numerous studies showing that a wide range of crops in a large number of regions now produce smaller harvests (IPCCAR5-SPM). The Inuit can feel the permafrost soften under their feet, leading built structures to collapse. Pacific Islanders have seen their freshwater supplies contaminated with saltwater and coastlines inundated as sea level rises. Numerous countries around the world increasingly experience extreme floods and droughts. The IPCC itself admits that “not all regional effects of climate change are known,” but all of these trends were predicted. If current predictions for the future hold true, as is likely, the future looks bleak. Sea level will continue to rise as glaciers melt, bringing landlocked ice into the oceans. In addition, the oceans themselves will thermally expand as the global temperature rises. There will also be positive feedback – changes that amplify the trend. for instance, melting permafrost will release massive amounts of greenhouse gases. Less snow and ice cover will mean that more heat is absorbed by darker surfaces. furthermore, numerous natural systems – coral reefs, mangroves, Arctic and Alpine ecosystems, boreal and tropical forests, prairie wetlands, and grasslands – will struggle to survive as the climate changes; if these natural systems shrink, they will not be able to trap as much carbon dioxide. Another result will be a greater risk of species extinction and lower biodiversity. In Europe, rivers will increasingly flood, and the risk of floods, erosion, and wetland loss will increase in coastal areas everywhere. Industrialized countries have emitted the most GHGs, but developing countries – the ones least able to adapt to climate change – will be impacted the most. The areas hit the hardest include large parts of Africa, Asia, and the Pacific rim. The long-term effects of global warming will be catastrophic. The Greenland ice sheet could melt completely, thereby eventually raising sea level up to seven meters. There is also new evidence that Antarctic ice is now at the risk of melting based on increased rates of ice discharge. As this freshwater enters the ocean, the Gulf Stream in the Atlantic could slow down or stop completely. The result would be a much different climate for Europe, which depends on the Gulf Stream to bring up warm air from the South. furthermore, the Golf Stream is part of a global system of ocean currents, which could also be disrupted, leading to unexpected shifts in climates around the globe. As the IPCC puts it, “Never before has humanity been forced to grapple with such an immense environmental crisis.”

energy

[r]evolution

figure 1.5 | widespread impacts attributed to climate change based on the available scientific literature since the ar4

europe

polar regions (ARCTIC & ANTARCTIC)

small islands

north america

asia

africa

australasia central & south america

confidence in attribution to climate change

) INDICATES confidence range

vERy LOW

LOW

MED

HIGH

vERy HIGH

physical systems

biological systems

human and managed systems

GLACIERS, SNOW, ICE AND/OR PERMAfROST

TERRESTRIAL ECOSySTEMS

fOOD PRODuCTION

RIvERS, LAkES, fLOODS AND/OR DROuGHT

WILDfIRE

LIvELIHOODS, HEALTH AND/OR ECONOMICS

COASTAL ERROSION AND/OR SEA LEvEL EffECTS

MARINE ECOSySTEMS

impacts IDENTIfIED bASED ON AvAILAbLITy Of STuDIES ACROSS A REGION

note The latest scientific research finds “substantially more impacts in recent decades now attributed to climate change.” Note that the chart above shows only those impacts for which causality has been demonstrated for climate change. Other impacts may be linked to global warming in the future, so the list could grow. source IPCC-AR5-SPM.

1.2.4 extreme events

1.3 nuclear threats

Since 1950, some of the changes in extreme weather and climate events have been linked to human influences. Extremely cold temperatures have decreased, while extremely high temperatures have become more frequent. There is also been a noted increase in heavy precipitation in various reasons. Heat waves have become more common in Europe, Asia, and Australia. The impacts of heat waves, droughts, floods, cyclones, and wildfires have revealed the “significant vulnerability and exposure of some ecosystems and many human systems to current climate variability” (IPCC-AR5-SPM).

Nuclear energy is a relatively minor industry with major problems. Currently covering just 2.3 per cent of the world’s final energy consumption, nuclear’s share is set to decline over the coming decades.

If civilization continues to emit greenhouse gases, further warming is highly likely, with long-term, irreversible, and severe impacts on the entire climate. To prevent this calamity, greenhouse gas emissions need to be substantially reduced. Even then, significant resources will need to be devoted to future climate adaptation from current emissions (IPCC-AR5-SPM).

The amount of nuclear capacity added during last 15 years (2000-2014: 20,000 MW) (WNISR 2015) 2 was 17 times less than the new wind capacity built in the same period (356,000 MW) (REN21-2015). 3 Those new wind generators have a potential annual generation of 900 TWh – equal to 120 nuclear reactors with a capacity of 1000MW each. Despite the rhetoric of a ‘nuclear renaissance’ – a term the nuclear industry has used since around 2001, the industry is struggling with massive cost increases, construction delays and safety and security problems. japan’s major nuclear accident at fukushima following a tsunami came 25 years after the disastrous explosion in the Chernobyl nuclear power plant in the former Soviet union, showing that nuclear energy is an inherently unsafe source of power. As a result, Siemens declared its exit from the nuclear power sector in 2011 and now only focuses on the delivery of spare parts for the existing reactors along with operation and maintenance service. following the fukushima accident, the German Parliament resolved to shut all nuclear power plants by 2022, 4 including immediate the immediate closure of nearly half of them. That same year, Germany also passed a set of laws to further boost renewable energy and energy efficiency technologies. In the wake of the fukushima accident, 95% of Italians also voted in a plebiscite to reject nuclear energy. At the start of 2012, over 90% of the japan’s reactors were offline. There have been no significant problems with the electricity supply with only 3 of 54 in operation.

world energy [r]evolution a sustainable world energy outlook

image satellite iMage of JaPan’s dai ichi Power Plant showing daMage after the earthquake and tsunaMi of 2011.

references 2 3 4

(WNISR 2015) WORLD NuCLEAR INDuSTRy STATuS REPORT 2015, MyCLE SCHNEIDER, ANTONy fROGGATT ET. AL.; PARIS / LONDON 2015. (REN 21-2015); GLObAL STATuS REPORT RENEWAbLES 2015, REN 21; PARIS. ATOMAuSSTIEGSGESETz – 30 juNE 2011.

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[r]evolution

1.3.1 no solution to climate protection

1.3.2 the dangers of nuclear power

The nuclear industry promises that nuclear energy can contribute to both climate protection and energy security; however, their claims need to be reality-checked.

Electricity from nuclear power does produce less carbon dioxide than fossil fuels, but nuclear power poses multiple threats to people and the environment during operation. The main risks are for safety of the reaction, nuclear waste disposal and nuclear proliferation. These three risks are detailed below and are the reasons nuclear power has been discounted as a future technology in the Energy [R]evolution Scenario.

The most recent World Energy Outlook 2015 and the Special Energy and Climate Report published by the International Energy Agency, 5 includes a bridge scenario for a future energy mix to keep global carbon concentration below 450ppm. While renewables and energy efficiency play the largest role to achieve this target, a large expansion of nuclear power up to 2030 is still included. The technical assumption is that the installed capacity will be increased from 392 GW in 2013 up to 552 GW in 2030 – an additional 150 GW. To reach this goal, 10 GW – 7 to 10 nuclear reactors – need to come on line every year, an extremely unlikely given the “performance” of the nuclear industry. This pathway would be very expensive and hazardous, while hardly helping to reduce the emission of greenhouse gases. A more realistic analysis shows: • The IEA scenario assumes investment costs of uS$ 4,800/kWe installed, in line with what the industry has been promising. The reality indicates costs of new plant are three to four times higher (see box). • Massive expansion of nuclear energy comes with an increase in related hazards: the risk of serious reactor accidents like in fukushima, japan; the growing stockpiles of deadly high level radioactive waste which will need to be safeguarded for hundreds of thousands of years; and potential proliferation of both nuclear technologies and materials through diversion to military or terrorist use. • Climate science says that we need to reach a peak of global greenhouse gas emissions before 2020. Even if the world’s governments decided on strong nuclear expansion now, not a single new reactor would start generating electricity before 2020 because it typically takes at least ten years from decision to commissioning. Any significant contribution from nuclear power towards reducing emissions would come too late to help save the climate.

safety risks

Several hundred accidents have occurred in the nuclear energy industry since it began, including Windscale (1957), Three Mile Island (1979), Chernobyl (1986), Tokaimura (1999) and fukushima (2011). Despite the nuclear industry’s assurances that a nuclear accident of the Chernobyl scale could never happen again, an earthquake and subsequent tsunami in japan caused leaks and explosions in four reactors at the Daiichi nuclear power plant. Large areas around the plant have been seriously contaminated with radioactivity from the plant. Areas up to 50 km from the facility have been evacuated, and food and water restrictions apply at distances exceeding 100 km. The impacts on the lives of hundreds of thousands of people and on the japanese economy will be felt for decades to come. The fukushima disaster proves the inherent safety problems with nuclear energy. • All existing nuclear reactors need continuous power to cool the reactors and the spent nuclear fuel, even after the reactor has shut down. In 2006, the emergency power systems failed at the Swedish forsmark plant for 20 minutes during a power outage, and four of Sweden’s ten nuclear power stations had to be shut down. If power had not been restored, there could have been a major incident within hours. • A nuclear chain reaction must be kept under control, and harmful radiation must, as far as possible, be contained within the reactor, with radioactive products isolated from humans and carefully managed. Nuclear reactions generate high temperatures, and fluids used for cooling are often kept under pressure. Together with the intense radioactivity, these high temperatures and pressures make operating a reactor difficult and complex. • The risks from operating reactors are increasing, and the likelihood of an accident is now higher than ever. Most of the world’s reactors are more than 25 years old and therefore more prone to age-related failures. Many utilities are attempting to extend the life of their reactors, which were designed to last only 30 years, up to 60 years, which poses new risks.

references 5

(IEA-WEO-SR-2015) INTERNATIONAL ENERGy AGENCy; WORLD ENERGy OuTLOOk 2015 – SPECIAL REPORT ENERGy AND CLIMATE; juNE 2015; PARIS/fRANCE.

world energy [r]evolution a sustainable world energy outlook

• A series of institutional failures set the stage for the fukushima Daiichi disaster including a system of industryled self-regulation, the industry’s overconfidence, its inherently dismissive attitude towards nuclear risks, and its neglect of scientific evidence. Institutional failures are the main cause of all past nuclear accidents, but the nuclear industry’s risk assessments fail to take those into account. • Nuclear utilities are reducing safety-related investments and have limited staff numbers, but they are increasing reactor pressure and operational temperature and the burnup of the fuel. This accelerates ageing and decreases safety margins. nuclear waste

Despite 50 years radioactive waste, there is no solution for the long-term storage and safeguarding of these dangerous materials. Disposal sites of low-level radioactive waste have already started leaking after only decades, even though highly radioactive waste needs to be safely contained for hundreds of thousands of years. The nuclear industry claims it can ‘dispose’ of its nuclear waste by burying it deep underground, but this approach will not isolate the radioactive material from the environment forever. A deep dump only slows down the release of radioactivity into the environment. Power plant developers try to predict how fast a dump will leak so that it can claim that radiation doses to the public living nearby in the future will be “acceptably low”. but scientific understanding is not sufficiently advanced to make such predictions with any certainty. As part of a campaign to build new nuclear stations around the world, the industry claims that public acceptability, not technical obstacles, is the main problem that burying radioactive waste faces. It cites nuclear dumping proposals in finland and Sweden but without scientific backing for its claims of safe disposal. The most hazardous waste is the spent fuel removed from nuclear reactors, which stays radioactive for hundreds of thousands of years. In some countries, the situation is exacerbated by ‘reprocessing’ this spent fuel, which involves dissolving it in nitric acid to separate out weapons-usable plutonium. This process leaves behind a highly radioactive liquid waste. There are about 270,000 tonnes of spent nuclear waste fuel in storage, much of it at reactor sites. Spent fuel is accumulating at around 12,000 tonnes per year, with around a quarter of that used for reprocessing. 6 The least damaging option for waste already in existence is to store it above ground, in dry storage at the site of origin. However, this option also presents major challenges and threats, as was seen in the fukushima accident where there was major disruption to the cooling of the spent nuclear fuel. The only real solution is to stop producing the waste.

nuclear proliferation

Manufacturing a nuclear bomb requires fissile material - either uranium-235 or plutonium-239. Most nuclear reactors use uranium as a fuel and produce plutonium during operation. It is impossible to adequately prevent the diversion of plutonium to nuclear weapons. A small-scale plutonium separation plant can be built in four to six months, so any country with an ordinary reactor can produce nuclear weapons relatively quickly. As a result, nuclear power and nuclear weapons have grown up like Siamese twins. Since international controls on nuclear proliferation began, Israel, India, Pakistan and North korea have all obtained nuclear weapons; aside from Israel and North korea, all of these countries also have nuclear power plants. The tasks of International Atomic Energy Agency (IAEA) and the Nuclear Non-proliferation Treaty (NPT) are inherently contradictory: to promote the development of ‘peaceful’ nuclear power whilst at the same time trying to stop the spread of nuclear weapons. Israel, India and Pakistan all used their civil nuclear operations to develop weapons capability, operating outside international safeguards. North korea developed a nuclear weapon even as a signatory of the NPT. A major challenge to nuclear proliferation controls has been the spread of uranium enrichment technology to Iran, Libya and North korea. The former Director General of the International Atomic Energy Agency, Mohamed Elbaradei, has said that “should a state with a fully developed fuel-cycle capability decide, for whatever reason, to break away from its non-proliferation commitments, most experts believe it could produce a nuclear weapon within a matter of months”. 7 The united Nations Intergovernmental Panel on Climate Change has also warned that the security threat of trying to tackle climate change with a global fast-breeder programme (using plutonium fuel) “would be colossal”. 8 All of the reactor designs currently being promoted around the world could be fuelled partly with MOx (mixed oxide fuel), from which plutonium can be easily separated. Restricting the production of fissile material to a few ‘trusted’ countries will not work. Instead, it would create greater security threats through inequity and resentment. A new uN agency is needed to tackle the twin threats of climate change and nuclear proliferation by phasing out nuclear power and promoting sustainable energy, which would promote world peace rather than threaten it.

references 6 7 8

‘WASTE MANAGEMENT IN THE NuCLEAR fuEL CyCLE’, WORLD NuCLEAR ASSOCIATION, INfORMATION AND ISSuE bRIEf, fEbRuARy 2006 (WWW.WORLD-NuCLEAR.ORG/INfO/INf04.HTM). MOHAMED ELbARADEI, ‘TOWARDS A SAfER WORLD’, ECONOMIST, 18 OCTObER 2003. IPCC WORkING GROuP II, ‘IMPACTS, ADAPTATIONS AND MITIGATION Of CLIMATE CHANGE: SCIENTIfIC-TECHNICAL ANALySES’, 1995.

c l i M at e a n d e n e r gy P o l i cy international climate policy the unfccc and the kyoto protocol

renewable energy policies

policy recommendations

2 “

win-win-strategy: reducing carbon emissions with renewables”

image nine Million cadMiuM telluride solar Modules now cover Part of carrizo Plain in southern california. the Modules are Part of toPaz solar farM, one of the largest Photovoltaic Power Plants in the world. at 9.5 square Miles (25.6 square kiloMeters), the facility is about one-third the size of Manhattan island, or the equivalent of 4,600 football fields. when oPerating at full caPacity, the 550-Megawatt Plant Produces enough electricity to Power about 180,000 hoMes. that is enough to disPlace about 407,000 Metric tonnes of carbon dioxide Per year, the equivalent of taking 77,000 cars off the road.

world energy [r]evolution a sustainable world energy outlook

2 To make the Energy [R]evolution a reality, immediate political action is required. There are no economic or technical barriers to move to 100% renewable energy. Governments regulate energy markets, both for supply and demand; they can educate everyone from consumers to industrialists and stimulate the market for renewable energy and energy efficiency by implementing a wide range of economic mechanisms. They can also build on the successful policies already adopted by other countries. To get started, governments need to agree on further binding emission reduction commitments under the uNfCCC process. 2.1 international climate policy - the unfccc and the kyoto protocol Recognising the global threats of climate change, the signatories to the 1992 uN framework Convention on Climate Change (uNfCCC) followed up with the kyoto Protocol in 1997. It entered into force in early 2005, and its 193 members meet continuously to negotiate further refinement and development of the agreement. Only one major industrialised nation, the united States, has not ratified the protocol. In 2011, Canada announced its intention to withdraw from the Protocol. In Copenhagen in 2009, the 195 members of the uNfCCC were supposed to deliver a new climate change agreement towards ambitious and fair emission reductions. unfortunately, they failed at this conference. At the 2012 Conference of the Parties in Durban, there was agreement to reach a new agreement by 2015 and adopt a second commitment period at the end of 2012. During the 2014 conference in Lima, the uS and other developed countries emphasised the need to be “realistic” and “nationally determined” with future emission cuts, and resisted stronger action on finance and adaptation, in particular for the most vulnerable countries. India and China, on the other hand, allied with oil-producing states in an effort to protect themselves from taking on tougher and more binding emissions cuts in the future. The result was a messy compromise that sets no common time frame for future pollution cuts. While the Lima decision does require countries to submit basic information about the climate actions they plan to include in the next conference agreement (Paris COP21 in 2015), it also downgrades the proposed assessment of the fairness and adequacy of countries’ contributions partly as a result of pressure from China and India. Instead, the secretariat is to compile a mere technical paper assessing the aggregate effect of the targets. The outcome in Lima established no clear requirement for rich countries to include climate finance in their reported actions before Paris, nor does it establish a clear road-map for scaling up finance towards the 100 billion dollars a year promised by 2020. However, over time it does put adaptation on a more equal footing with emission reductions. 26

In December 2015, the global community will meet in Paris for the 21st uN Conference of the Parties (COP21) to negotiate and sign a new global agreement to address dangerous global warming. The success of the Paris COP hinges upon countries agreeing to support a vision for 100% clean renewable energy by 2050 and increased forest protection. The formal negotiating text was released in March 2015 and further negotiated in bonn from 1-11 june 2015. Meanwhile, the global emissions landscape is changing rapidly. As a result of declining coal consumption in China, global energy-related CO2 emissions remained stable in 2014 for the first time in 40 years, despite continued economic growth. If global mitigation endeavours are strengthened, this trend is set to continue. This new landscape provides a greater chance that the coal, oil and nuclear industries – which continue to fight to maintain their dominance by propagating the outdated notion that citizens need their dirty energy – will face dramatic changes in both energy markets and support from governments. countries´ commitments Countries’ national commitments

(also known as intended nationally determined contributions INDCs) are key components of the Paris agreement as they are the tools for immediate and drastic emissions cuts. Parties were asked to submit their proposed mitigation commitments well in advance of the Paris conference. Thus far, several major emitters, including China, have already presented their plans. It is crucial that the remaining countries submit as soon as possible. international climate policy - looking ahead Countries should

not only present their short-term commitments, based on 5-year periods, but also outline long-term plans for a just transition to an economy built on 100% clean renewable energy. Countries should include other policy commitments in their INDCs, such as renewable energy and energy efficiency targets along with commitments to stop fossil fuel subsidies. Rich countries and other countries in a position to do so should also address the question of climate finance in their commitments to ensure predictability and adequacy for vulnerable countries. an effective climate agreement should include strong short-

term action and set out a clear long-term pathway. key elements include the following: • a strong long-term goal: Phase-out of fossil fuels and nuclear power by 2050 through a just transition towards 100% renewable energy, as well as the protection and restoration of forests. A clear signal to decision-makers and investors at

all levels that the world is moving towards phasing out carbon emissions entirely and accelerating the transition to 100% renewable energy is needed. Countries’ short-term emission reduction commitments must align with this longterm goal and support transformational change, ensuring both fairness and solidarity.

energy

[r]evolution 2 • a 5-year cycle process for country commitments starting 2020 All countries’ commitments should follow a 5-year commitment period starting in 2020, which would form the first period of the Paris Protocol. Moving forward, each period would further deepen the commitments, allowing no back-sliding. 5-year commitment periods incentivize early action, allow for dynamic political responses and avoid locking in low levels of ambition. They allow for a timely adaptation to the technological advances of renewable energies and energy efficiency. • legally binding: A legally binding protocol - including common accounting rules for mitigation and finance - will compel leaders to act in a strong way; legally binding obligations are the real expressions of political will, ensuring durability in the face of political changes and increased ambition over time. • shifting subsidies away from fossil fuels. All countries should commit to phase-out all subsidies- both production and consumption - for fossil fuels until 2020 subsidies. • strong commitment for adaptation, finance and loss and damage: The Paris Protocol should acknowledge that less mitigation action means a greater need for adaptation, especially finance. Consequently, an adaptation goal should be established to ensure that the level of support meets vulnerable countries’ needs under the actual warming anticipated. A roadmap must be decided in Paris for how to meet the 100bn uSD commitment for climate financing by 2020. • bring down emissions before 2020. The gap between the agreed upon goal of keeping warming below 2°C/1.5°C and what countries actually intend to do by 2020 is widely acknowledged. The pledges during time of writing of this report (mid-2015) would lead us into a world of 3 or more degrees warming, with all its devastating consequences for humans and ecosystems. While a process on how to bring the emissions down was established at COP17 in 2011, countries are still – four years later – failing to agree upon sufficient action to mitigate greenhouse gases. In Paris at the latest, governments and corporate leaders need to provide innovate solutions for breaking the stalemate and laying the groundwork for bold actions before 2020.

2.1.1 international energy policy - energy policy and market regulation

On many energy markets, renewable energy generators currently compete with old nuclear and fossil fuel power stations on an uneven playing field. Consumers and taxpayers have already paid the interest and depreciation on the original investments, so the generators are running at a marginal cost. Political action is needed to overcome market distortions so renewable energy technologies can compete on their own merits. While governments around the world are liberalising their electricity markets, the increasing competitiveness of renewable energy should lead to higher demand. Without political support, however, renewable energy remains at a disadvantage, marginalised after decades of massive financial, political and structural support for conventional technologies. Developing renewables will therefore require strong political and economic efforts, for example through laws that guarantee stable payment for up to 20 years. Renewable energy will also contribute to sustainable economic growth, high quality jobs, technology development, global competitiveness, and industrial and research leadership. 2.2 renewable energy policies In 2014, the global market trended towards increased levels of renewable energy, with variable generation from wind and solar leading the way. More electricity was used as a result, replacing fuels both for heating and transport and changing energy markets significantly, particularly in developed countries. Global subsidies for fossil fuels and nuclear power remain high despite reform efforts. Creating a level playing field can lead to a more efficient allocation of financial resources, helping to strengthen initiatives for the development and implementation of energy efficiency and renewable energy technologies. Removing fossil-fuel and nuclear subsidies globally would more accurately reflect the true cost of energy generation. Cost competitiveness per unit no longer remains a barrier; however, grid-connected renewable energy power plants and the secure transport and delivery of electricity represent an increased investment risk because it leads to uncertainty for overall electricity sales from RE plants. In 2014, there was a growing trend to link several policies together (such as renewable energy targets, feed-in tariffs or tendering, and grid access). The movement towards 100% renewable energy targets for regions, islands, large cities and whole countries continued to grow over the course of 2014. The following section about the status of renewable energy policies by the end of 2014 is based on an analysis published by the Renewable Energy Network for the 21st Century (REN21) (REN21 – 2015). 1

references 1

REN21 – RENEWAbLES 2015 – GLObAL STATuS REPORT; juNE 2015, PARIS / fRANCE.

world energy [r]evolution a sustainable world energy outlook

2 2.2.1 status of renewable energy policies for electricity

Targets and supporting policy tools to promote renewable energy for power generation continued to receive the majority of attention from policymakers, outpacing those set for the heating, cooling, and transportation sectors. • targets have been identified in 164 countries as of early 2015 and were added or revised in 11 countries in 2014. • feed-in tariffs (fITs) have now been enacted in 108 jurisdictions at the national or state/provincial level. Egypt was the only country adding a new national fIT in 2014, but a number of existing policies were amended with changes varying by region, continuing the trend in recent years. Countries including bulgaria, Germany, Greece, Italy, japan, Russia, Switzerland, and the Philippines reduced rates, while rates were increased and/or eligibility was expanded in Algeria, Denmark, Malaysia, Poland, and vietnam. China enacted a slate of revisions, simultaneously opening fITs to new technologies and reducing rates for some previously covered technologies. • tendering both technology-neutral and technology-specific tendering continues to be adopted by a growing number of countries, with 60 countries having utilized renewable energy tenders as of early 2015. The European Commission issued guidelines to begin a continent-wide shift away from fITs towards tenders. Poland indicated its intention to phase out its green certificate scheme in favor of tenders. • new net-metering policies were added in three countries, all in Latin America. • renewable Portfolio standards (rPs) policies continue to face opposition in a number of uS States. In 2014, Ohio became the first state to freeze its RPS, and in 2015 West virginia became the first state to remove its (voluntary) RPS entirely. An estimated 126 countries had adopted some form of financial support policy to promote renewable energy technologies by early 2015. • barriers to renewable energy: Charges or fees on renewable energy have been introduced in an increasing number of countries. In Europe, Germany, Austria and Italy enacted new charges on self-consumed solar Pv, joining fellow Eu member states including the Czech Republic, Greece, and Spain with fees and/or taxes on renewable energy output. 2.2.2 status of renewable energy policies for heating and cooling

Policies for renewable heating and cooling are slowly gaining more attention from national policymakers. An estimated 45 countries worldwide had targets for renewable heating or cooling in place by early 2015. In Europe, the majority of targets in Eu and Energy Community Member States have been introduced through each country’s National Renewable 28

Energy Action Plan (NREAP), while other countries have adopted technology specific targets focused on specified capacity or new installations of renewable heating systems. • solar-specific renewable heat mandates were in place in 12 countries at the national or state/provincial level, and technology-neutral mandates were in place in an additional 9 countries by early 2015. South Africa was the only country to institute a new mandate during 2014. • financial incentives continued to be the most widely enacted form of policy support for renewable heating and cooling systems in 2014. Algeria, Chile, Romania, and Slovenia all re-introduced incentive schemes that had expired in previous years, the Czech Republic, India, and kenya strengthened existing schemes, and the uS states of Minnesota and New york established new rebate programs in 2014. 2.2.3 renewable energy transport policies

The majority of transport-related policies continued to focus on developments in the biofuel sector and road transport; however, other modes of transportation are attracting attention as well. Policies promoting the linkage between electric vehicles and renewable energy have received little attention to date. The debate over the sustainability of first-generation biofuels continued worldwide in 2014, with European energy minsters agreeing to a 7% cap on the contribution of first-generation biofuel to meet the Eu-wide 10% renewable transport fuel target. Italy became the first country in Europe to enact a mandate promoting a specific share (0.6% by 2018) of second-generation biofuels. biofuel blend mandates are now in place in 34 countries, with 32 national mandates and 26 state/provincial mandates. Within these policy frameworks, 45 jurisdictions now mandate specified shares of bioethanol, and 27 mandate biodiesel blends, with many countries enacting both. Argentina, brazil, Malaysia, Panama, vietnam, and the uS state of Minnesota all strengthened existing blend mandates in 2014. 2.2.4 city and local government renewable energy policies

Cities continue to set and reach ambitious targets for renewable energy use which are also influenced by regions and countries with 100% renewable energy targets. joining a growing global movement of cities, new 100% targets were set in fukushima (japan) and Maui County, Hawaii (uSA). burlington, vermont (uSA), reached its 100% renewable electricity goal in 2014. Municipal policymakers in countries including brazil, China, India, and the united Arab Emirates continued a growing trend of utilizing municipal oversight of build code regulations

energy

[r]evolution 2 to mandate the deployment of renewable power generation and renewable heat technologies. Public-private partnerships and community power systems are increasingly being utilized to increase renewable energy at the local level. In the united States, over 2,000 communities have already created community power systems. An additional 800 have created electricity co-operatives to increase local control over power generation, while the CO-POWER project was inaugurated in Europe to support community power development across 12 European countries. District heating and cooling systems have emerged as an important measure, helping to facilitate the scale-up of renewable energy, with Dubai (uAE) and Paris (france) leading in 2014. In Europe, primarily in northern countries such as Denmark, large-scale solar thermal heating plants are increasingly being developed for connections to district heat networks. Municipal policymakers continued to use their purchasing authority to support renewable energy in their cities. Cities such as Paris (france) and San francisco (uSA) purchased electric and biofuel vehicles for city fleets, including buses used in public transportation systems. 2.2.5 distributed renewable energy in developing countries

More than one billion people or 15% of the global population still lack access to a power grid. With a total installed capacity of roughly 147 GW, all of Africa has less power generation capacity than Germany. Moreover, approximately 2.9 billion people lack access to cleaner forms of cooking. Energy companies invested about uSD 63.9 billion in off-grid solar Pv in 2014. bank of America (uSA) pledged uSD 1 billion to help finance distributed renewable energy projects that normally would not pass risk assessments. It also agreed to seed a Catalytic finance Initiative to stimulate at least uSD 10 billion of new investment in high-impact clean energy projects. The aim is for such initiatives to help develop innovative financing mechanisms, reduce investment risk and attract a broader range of institutional investors to the sector. There were new initiatives related to clean cooking during 2014. In july, Ecuador started executing a plan to introduce 3 million solar induction cooktops by 2016. Guatemala established a Cluster of Improved Cook Stoves and Clean fuels, representing individuals and organizations who work in these two areas. bangladesh announced a Country Action Plan for Clean Cook Stoves. India launched the unnat Chulha Abhiyan Programme to develop and deploy 2.75 million clean stoves by 2017. Several African countries, including Nigeria and Senegal, also have programs to distribute millions of clean cook stoves. Some 30 transnational programs and 20 global networks support national distributed renewable energy programs. The

Sustainable Energy for All Initiative (SE4ALL), Power Africa program, the Energizing Development Program, the Global Alliance for Clean Cook Stoves, and the Global Lighting and Energy Access Partnership are playing a key role in further distribution of distributed renewable energy, especially in least developed countries. In addition to existing, well established technologies such as solar home systems and micro hydro dams, 2014 witnessed the evolution of new types of equipment, configurations, and applications. Thermoelectric generator (TEG) stoves utilize their own heat to produce power that operates the blower or fan, eliminating the need for an external source of electricity and increasing the efficiency of combustion. flexi-biogas systems use balloon (or tube) digesters made from a polyethylene or plastic bag, making them mobile and extremely lightweight. Pico-wind turbines offer a very lowcost technology for powering remote telecommunications. Solar-powered irrigation kits enable farmers to grow highvalue fruits and vegetables. Ancillary services and monitoring are making use of digitization, and the “internet of things” facilitates improved after-sales, better customer service, and lower costs, enabling companies to reach more customers. Solar direct current (DC) micro-grids offer superior compatibility with certain electric appliances and can eliminate the need for an inverter. bundling of products and services together into hybridized or integrated packaged systems— especially bundles that promote electricity and appliance usage, telecommunications, and/or cooking—are a high-impact innovation. 2.2.6 energy efficiency: renewable energy’s twin pillar Success stories for energy efficiency standards Efficiency standards proved very successful in 2014. building standards and the construction of passive houses were implemented, as were standards for electrical appliances in several developing and emerging economies. The focus has been on efficiency improvements in road transport, including fuel economy improvements in private vehicles, increased penetration of electric (Ev) and hybrid (HEv) vehicles, and shifts to more sustainable modes of travel.

In 2013, more than 150 cities around the world had implemented some kind of building efficiency standard. by 2014, 81 countries had introduced energy standards and labeling programs, as well as mandatory energy performance standards covering 55 product types, with refrigerators, room air conditioners, lighting, and televisions being the most commonly regulated. by the end of 2013, standards for electric motors used in industrial applications had been introduced in 44 countries, including brazil, China, South korea, and the united States. As of late 2014, vehicle fuel economy standards covered 70% of the world’s light-duty vehicle market. 29

world energy [r]evolution a sustainable world energy outlook

2 2.3 policy recommendations Countries around the world are at varying levels of development with RE. While some are just starting to deploy modern RE - beyond traditional biomass and hydro – others have already reached high penetration levels, particular for solar and wind in the electricity sector. Globally, policies have largely driven the expansion of renewable energy. The number of countries promoting renewables through direct policy support continued to grow in 2014, albeit at varying rates and in response to diverse drivers. As circumstances change and level of RE increases, the policy mechanisms required will change as well. While grid integration issues due to ever increasing shares of wind and solar Pv are most pressing in developed countries, access to technology and financial resources is the highest priority in developing countries. Policy frameworks must be stable and predictable in order to underpin the sustained deployment of renewable energy. The industry needs predictable policy frameworks in order to be ready to invest, build up production capacities, develop new technologies and expand skilled employees. Moreover, there is a close correlation between supporting policies and the cost of renewable energy technology. Price support mechanisms for renewable energy are a practical way to correct market failures in the electricity sector. They aim to support market penetration of those renewable energy technologies, such as wind and solar thermal, that currently suffer from unfair competition due to direct and indirect support to fossil fuel use and nuclear energy, and to provide incentives for technology improvements and cost reductions so that technologies such as Pv, wave and tidal can compete with conventional sources in the future. Overall, there are two types of incentive to promote the deployment of renewable energy. These are fixed Price Systems and Renewable Quota Systems (referred to in the uS as Renewable Portfolio Standards). In the former, the government sets the price (or premium) paid to the power producer and lets the market determine the quantity; in the latter, the government sets the quantity of renewable electricity and leaves it to the market to determine the price. both systems create a protected market against a background of subsidised, depreciated conventional generators whose external environmental costs are not accounted for. These policies provide incentives for technology improvements and cost reductions, leading to cheaper renewables that will be able to compete with conventional sources in the future. The main difference between quota-based and price-based systems is that the former tends to promote the renewable energy source that is the cheapest, which is generally

onshore wind power. In doing so, this policy thus gives the most support to the energy source that needs the least. In contrast, price-based policies spread support across numerous renewable energy sources more equally, including those that are currently more expensive and need greater support. In doing so, they ramp up fledgling industries to bring costs down. However, competition between technology manufacturers is the most crucial factor in bringing down electricity production costs. Only if large volumes of equipment can be manufactured, cost reduction potential can be fully exploited. So the goal of fighter policy should be large-scale deployment towards bringing about economies of scale among manufacturers. A bankable support scheme for renewable energy projects provide long-term stability and lead to lower “soft costs” (less red tape). In any case, renewable power generation requires priority access and dispatch on the power grid so renewables are not curtailed in favour of more polluting power sources. The substantial cost reductions of renewables are largely the result of policy support, which has attracted significant investments leading to economies of scale. However, abrupt policy change of policies, such as a sudden reversal of feedin tariffs, can have major negative impacts for the industry as a whole. Therefore, any transition towards a new policy system requires sufficient time, both in the lead-up to implementation and in duration of the new policy itself so that industry can adapt its business model. Today, the penetration of renewables is no longer a question of technology or economics but one of developing more flexible markets, smarter energy systems and – especially for developing countries – access to finance. This policy shift must be underpinned by the appropriate regulations, business, and finance models. 100% renewables: aiming high to drive the transition

High targets for renewable energy – across all sectors – trigger innovation. A complete transition towards renewable energy requires the development of new policies to support business models in an ever changing energy market design. Setting ambitious long-term renewable energy targets will help to organize the energy transition across all three sectors. Thus new policies are needed to restructure the electric power and heating markets, and to develop regulations to provide a fair and efficient basis for blending centralized and distributed generation with demand-flexibility measures. Our thinking about future energy systems needs to focus on how existing infrastructure must be adapted and enhanced to accommodate the ongoing integration of large shares of renewable energy.

energy

[r]evolution 2 harnessing local action to ensure global renewable energy uptake

Today, local governments are leaders in the advancement of renewable energy, particularly in combination with energy efficiency improvements. They regularly exceed efforts made by state, provincial, and national governments. Motivated to create local jobs, reduce energy costs, address pollution issues, and advance their sustainability goals, hundreds of local governments worldwide have set renewable energy targets and enacted fiscal incentives or other policies to foster the deployment of renewables. Governments at the community, city, regional, island, and even country levels have begun to forge their own transition pathways towards a 100% renewable energy future. A better linking of local renewable energy developments with those at the national level will be key to driving the energy transition. creating a level playing field for the entire energy sector

Global subsidies for fossil fuels and nuclear power remain high despite reform efforts. The exact level of subsides is unknown; estimates range from uSD 544 billion (World bank) to uSD 1.9 trillion per year (International Monetary fund), depending on how “subsidy” is defined. Whichever number is chosen, subsidies for fossil fuels and nuclear power are significantly higher than financial support for renewables. Electricity price subsidies for consumers in developing countries should be shifted towards Distributed Renewable Energy (DRE). Creating a level playing field can lead to a more efficient allocation of financial resources, helping to strengthen initiatives for the development and implementation of energy efficiency and renewable energy technologies. Removing fossil-fuel and nuclear subsidies globally would reflect more accurately the true cost of energy generation. improving energy data to monitor advancements in achieving a renewable energy transition

Reliable, timely, and regularly updated data on renewable energy are essential for establishing energy plans, defining targets, designing and continuously evaluating policy measures, and attracting investment. The data situation for renewable energy – especially in the power sector - has improved significantly in recent years. better record-keeping, accessibility, and advances in communication and collection methods have contributed greatly to this development. Nonetheless, the availability, accessibility, and quality of data for distributed renewable energy and bioenergy is still poor. To overcome some of these existing data gaps, it is essential to develop innovative and collaborative approaches to data collection, processing, and validation. until recently, “acceptable data” have been limited to official statistics (formal data). for an accurate and timely understanding of the status of the renewable energy sector, official renewable energy data need to be supplemented with informal data.

The addition of informal data can improve coverage of sectors and regions and help resolve the lack of data; however, previously uninvolved players from varying sectors would then need to be involved. Many of these individual and institutional actors typically have already engaged in some form of data collection but are unaware of the importance of their data or lack the means of sharing them. Additionally, cross-sector methods and approaches for data collection must be considered. by utilizing links between energy and other sectors, such as health and agriculture, data gaps can be filled and data quality improved. There is a critical need to broaden the definition of renewable energy data, to collect data in a regular and more systematic manner, and to increase transparency. renewable power: (energy) developed countries

system

thinking

required

With increased shares of variable solar and wind power generation, a variety of technologies need to be integrated in one resilient power supply system. Thus, policy developments should shift away from single-technology support schemes towards ones that support a combination of diverse technologies. Policies need to transform power grids to become more flexible, increase demand-side integration, and integrate power systems with transport, buildings, industry, and heating and cooling sectors. utilities and grid operators will also play an important role in managing demand and generation in renewable energydominated energy systems. Demand-side management of industries, transport systems and households and the operation of distributed generation fleets require different energy policies to enable new business models. Achieving a renewable energy technology mix which can be used for dispatching - also across the power, heating/cooling and transport sector - is important. Heating systems, such as heat pumps or district heating networks can be used to better integrate solar and wind power. The German “Energiewende” (German for “energy transition”) has inspired many countries, helping to build new momentum around renewable energy. Experiences with system integration in industrialized countries such as Spain, Germany, Denmark and the uS can help develop future concepts for developing countries to help establish trust that energy supply can fundamentally build on RE. the renewable heating and cooling sector lacks progress

To achieve the transition towards renewable energy, more attention needs to be paid to the heating and cooling sectors, as well as to integrated approaches that facilitate the use of renewables in this sector. Globally, heating and cooling accounts for almost half of total global energy demand. However, this sector continues to lag far behind the

world energy [r]evolution a sustainable world energy outlook

2 renewable power sector when it comes to policies that support technology development and deployment. Policies should make sure that specific targets and appropriate measures to support renewable heating and cooling are part of any national renewable energy strategy. They should include financial incentives; awareness-raising campaigns; training for installers, architects and heating engineers; and demonstration projects. for new buildings and those undergoing major renovation, a minimum share of heat consumption from renewable energy should be required, as is already implemented in some countries. At the same time, increased R&D efforts should be undertaken, particularly in the fields of heat storage and renewable cooling. Mandatory regulations in the building sector can also help increase the penetration of renewable technologies. Improving the accuracy of national data collection on heating and cooling supply and demand is also important. The distributed nature of heat supply and local demand make it difficult to know what sources are available and what is needed; this information is crucial for good policy development. The expansion of district heating networks supports both the development of renewable energy heating and benefits the integration of variable power generation. Heating networks can be utilized for demand side management, relieving pressure on power grids. A smart combination of heating and power grids can also reduce the need for grid expansion, decreasing costs further. getting the policy mix right in developing countries

In developing countries, access to financial resources, technology, and information is key. Many developing countries also have a steep energy demand, particularly in the industrial sector. Ensuring the energy supply for heavy industries and for small and medium enterprises is crucial for the economic development of these countries. With renewable energy – modular and highly standardized power technologies – expanding energy supply for all consumer groups is not a technological, but a political challenge. Access to expertise and financial resources requires stable, long-term energy policies. There is also an urgent need to address the lack of access to energy services and inefficiencies in the provision of energy services to the urban poor and rural communities. Improved energy access is crucial towards advancing the quality of life and socio-economic status of these populations, in turn contributing to political stability on national, regional and international levels and helping to improve economic growth and environmental sustainability. Renewables have a key role to play in increasing access through distributed solutions.

Stand-alone cooking and electricity systems based on renewables are often the most cost-effective options available for providing energy services to households and businesses in remote areas. Supporting the development of distributed renewable energy-based systems to expand energy access is essential. Combined with information and communication technology (ICT) applications for power management and end-user services, recent technical advances that enable the integration of renewables in minigrid systems allow for rapid growth in the use of mini-grids powered with renewables. There is growing awareness that off-grid, low-income customers can provide fast-growing markets for goods and services. The emergence of new business and financing models to serve them means that these energy markets are increasingly recognized as offering potential business opportunities. Despite some progress on expanding energy access in different parts of the world, some 1.3 billion people still lack access to electricity, and more than 2.6 billion people rely on traditional biomass for cooking and heating, with the related negative health impacts. In order to support the expansion of energy markets to reach full energy access – as promoted by SE4ALL – the public and private sector need to actively work together to ensure the financing of distributed renewable energy by developing and implementing support policies, establishing broader legal frameworks, and ensuring political stability. efficiency: set stringent efficiency and emissions standards for appliances, buildings, power plants and vehicles

Policies and measures to promote energy efficiency exist in many countries. Energy and information labels, mandatory minimum energy performance standards and voluntary efficiency agreements are the most popular measures. Effective government policies usually contain two elements those that use standards to push the market and those that use incentives to pull. both are an effective, low cost way to transition to greater energy efficiency. The japanese front-runner programme, for example, is a regulatory scheme with mandatory targets which gives incentives to manufacturers and importers of energyconsuming equipment to continuously improve the efficiency of their products. It operates by allowing today’s best models on the market to set the level for future standards.

energy

[r]evolution 2 support innovation in energy efficiency, low carbon transport systems and renewable energy production

Innovation will play an important role in the Energy [R]evolution, and it is needed for ever-improving efficiency and emissions standards. Programmes supporting renewable energy and energy efficiency are a traditional focus of energy and environmental policies because energy innovations face barriers all along the energy supply chain (from R&D to demonstration projects and widespread deployment). Direct government support through a variety of fiscal instruments, such as tax incentives, is vital to hasten deployment of radically new technologies that face a lack of industry investment. There is thus a role for the public sector towards increasing investments directly and in correcting market and regulatory obstacles that inhibit investment in new technology.

• electric vehicles: Governments should develop incentives to promote the further development of electric cars and other efficient and sustainable low-carbon transport technologies. Linking electric cars to a renewable energy grid is the best possible option to reduce emissions from the transport sector. • transport demand management: : Governments should invest in developing, improving and promoting low emission transport options, such as public and non-motorised transport, freight transport management programmes, teleworking and more efficient land use planning in order to limit journeys. the key requirements for effective (renewable) energy policies are:

Governments need to invest in research and development for more efficient appliances and building techniques, new forms of insulation, new types of renewable energy production (such as tidal and wave power), and a low-carbon transport future, such as the development of better batteries for plugin electric cars and renewable fuels for aviation. Governments need to engage in innovation themselves, both through publicly funded research and by supporting private research and development.

• long-term security for the investment: Investors need to know if energy policy will remain stable over the entire investment period (until the generator is paid off). Investors want a good return on investment, and while there is no universal definition of a “good return,” it depends to a large extent on the inflation rate of the country. Germany, for example, has an average inflation rate of 2% per year and a minimum return of investment expected by the financial sector is 6% to 7%. Achieving 10% to 15% returns is seen as extremely good and everything above 20% is seen as suspicious.

There are numerous ways to support innovation. The most important policies are those that reduce the cost of research and development, such as tax incentives, staff subsidies and project grants. financial support for research and development on ‘dead end’ energy solutions such as nuclear fusion should be diverted to supporting renewable energy, energy efficiency and distributed energy solutions.

• long-term security for market conditions: Investor need to know if the electricity or heat from the power plant can be sold to the market for a price that guarantees a good return on investment (ROI). If the ROI is high, the financial sector will invest, it is low compared to other investments, and financial institutions will not invest.

transport

• transparent Planning Process: A transparent planning process is key for project developers, so they can sell the planned project to investors or utilities. The entire licensing process must be clear and transparent.

• emissions standards: Governments should regulate the efficiency of private cars and other transport vehicles in order to push manufacturers to reduce emissions through downsizing, design and technology improvement. Improvements in efficiency will reduce CO 2 emissions irrespective of the fuel used. Afterwards, further reductions could be achieved with low-emission fuels. Emissions standards should provide for a mandatory average reduction of 5g CO 2 /km/year in industrialised countries. To dissuade car makers from overpowering high-end cars, a maximum CO 2 emissions limit for individual car models should be introduced.

• access to the grid: fair access to the grid is essential for renewable power plants. If no grid connection is available or if the costs to access the grid are too high, the project will not be built. In order to operate a power plant, investors must know if the asset can reliably deliver and sell electricity to the grid. If a specific power plant (such as a wind farm) does not have priority access to the grid, the operator might have to switch the plant off when there is an oversupply from other power plants or a bottleneck in the grid. This arrangement can add high risk to the project financing, which might then not be financed or only with a “risk-premium” that lowers the ROI.

world energy [r]evolution a sustainable world energy outlook

2 bankable renewable energy support schemes

Since the early development of renewable energies within the power sector, there has been an on-going debate about the best and most effective type of support scheme. The European Commission published a survey in December 2005, which concluded that feed -in tariffs are by far the most efficient and successful mechanism. A more recent update of this report, presented in March 2010 at the IEA Renewable Energy Workshop by the fraunhofer Institute underscores the same conclusion. The Stern Review on the Economics of Climate Change also concluded that feed -in tariffs “achieve larger deployment at lower costs”. Globally more than 40 countries have adopted some version of the system. Although the organisational form of these tariffs differs from country to country, some criteria have emerged as essential for successful renewable energy policy. At the heart of these is a reliable, bankable support scheme for renewable projects to provide long-term stability and certainty. bankable support schemes result in lower-cost projects because they lower the risk for both investors and equipment suppliers. The cost of wind power in Germany is up to 40% cheaper than in the united kingdom, for example, partly because the support system is more secure and reliable. for developing countries, feed-in laws would be an ideal mechanism to boost the development of new renewable energy. The extra costs to consumers’ electricity bills are an obstacle for countries with low average incomes. However, countries that build wind and solar projects today do not face the high costs that Germany, for instance, did only a few years ago, so the cost impact on countries that start now will be much lower. In order to enable technology transfer from Annex 1 countries under the kyoto Protocol to developing countries, a mix of a feed-in laws, international finance, and emissions trading could establish a locally based renewable energy infrastructure and industry with help from wealthier countries. finance for renewable energy projects is one of the main obstacles in developing countries. While large-scale projects have fewer funding problems, there are difficulties for small, community-based projects, even though they have a high degree of public support. The experience from micro credits for small hydro projects in bangladesh, for example, and wind farms in Denmark and Germany shows how economic benefits can flow to local communities. With careful project planning based on good local knowledge and understanding, projects can achieve local involvement and acceptance. When the community identifies with the project (as opposed to the project being forced on the community), the result is generally faster bottom-up growth of the renewable energy sector.

the four main elements for successful renewable energy support schemes are therefore:

• a clear, bankable pricing system. • Priority access to the grid with clear identification of who is responsible for the connection, and how it is incentivised.

• Clear,

simple procedures.

administrative

and

planning

permission

• Public acceptance/support. The first is fundamental, but it is insufficient without the other three elements. greenpeace and the renewable industry: required changes in the energy sector:

Greenpeace and the renewable energy industry share a clear agenda for the policy changes which need to be made to encourage a shift to renewable sources. the main demands are:

Phase out all subsidies for fossil fuels and nuclear energy.

internalise external (social and environmental) costs through carbon taxation and/or ‘cap and trade’ emissions trading.

mandate strict efficiency standards for all energy consuming appliances, buildings and vehicles.

establish legally binding targets for renewable energy and combined heat and power generation.

set ambitious and mandatory targets for the short, mid and long term along with supportive policies for their implementation;

reform electricity markets by guaranteeing priority access to the grid for renewable power generators.

establish cross-sectorial re support schemes to exploit synergies between the power, heating/cooling and transport sectors.

Provide defined and stable returns for investors, for example through feed-in tariff payments.

if changing circumstances, such as plummeting costs, require a transition to new policy mechanisms, interruption must be avoided and predictability needs to remain for investors;

10 . increase research and development budgets for renewable energy and energy efficiency.

t h e e n e r gy [ r ] e vo lu t i o n c o n c e P t status quo of the global energy sector

setting up an energy [r]evolution scenario

the energy [r]evolution logic

the “5 step implementation”

“

100% renewables requires system-thinking”

image tyPhoon Maysak, an unusually early storM for the northwest Pacific, strengthened abruPtly on the last day of March 2015 and grew into a category 5 suPer tyPhoon.

world energy [r]evolution a sustainable world energy outlook

Since the first Energy [R]evolution was published a decade ago, the energy sector has changed significantly. Renewable energy technologies have become mainstream in most countries as a consequence of dramatically reduced costs. A future renewable energy supply is no longer science fiction, but work in progress. However, growth rates of renewables – especially in the heating/cooling sector and in transport – are far too slow to achieve energy-related CO 2 reductions required to avoid dangerous climate change. A fundamental shift in the way we consume and generate energy must begin immediately and be well underway before 2020 in order to avert the worst impacts of climate change. 1 We need to limit global warming to less than 2° Celsius, above which the impacts become devastating. 3.1 status quo of the global energy sector Every day, The International Energy Agency published an evaluation of the current development of the Energy Sector in May 2015 (IEA – TCEP 2015), 2 which concluded that the implementation of renewables and energy efficiency is successful but too slow to meet the 2°C target. Here are some of the IEA’s conclusions: Costs: Increasingly, renewables are competitive with new fossil fuel plants, and the cost gap between renewable electricity and fossil power from new plants is closing worldwide. Nonetheless, markets still do not reflect the true environmental cost of power generation from fossil fuels. Policy: Power markets must be redesigned to accommodate variable, distributed renewables. Obstacles still exist for the financing of renewable energy projects and grid connections, thereby slowing down the transition. but the worst policy mistakes are uncertainty and retroactive changes. technology: Cogeneration and renewable heat have both grown in absolute terms, but are not increasing quickly enough as a share of energy supply. The share of cogeneration in power supply has even stagnated. Likewise, battery storage has mainly been developed for mobility up to now but is increasingly used for frequency regulation to integrate a greater share of variable renewables. mobility: Electric vehicles are catching on, with an increasing number of manufacturers now offering hybrid and electric options. fuel efficiency standards have also made light vehicles more efficient. The standard should now be applied to larger trucks and buses. buildings: The technologies are available, and targets are in place in many regions. However, the rate and depth of energy-efficient renovations needs to increase for true progress to be made in this sector because the building stock has a service life counted in decades. The Renewable Policy Network for the 21 Century (REN21) has undertaken a global renewable market analysis each year st

in june since 2004. The publication – “Renewables – Global Status Report” – is among the most comprehensive global and national surveys of the renewable industry sector. According to their latest edition, the global renewable energy market in 2014 was dominated by three power generation technologies: Solar photovoltaics (Pv), wind, and hydro. Combined, these technologies added 127 GW of new power generation capacity worldwide. by year’s end, renewables made up an estimated 60% of net additions to the global power capacity. In several countries renewables represented a higher share of added capacity (REN21-2015). 3 The increase in market volume and strong global competition led to significant cost reductions, especially for solar Pv and wind power. As a result, other renewable energy technologies were under pressure to lower costs, particularly in the heating and cooling sector due to the increased competitiveness of electricity-based heating systems. Cost competitive solar Pv in combination with electrical heat pumps became economically viable, negatively impacting the solar thermal collector market. While developments in the renewable energy, heating and cooling sector were slower than in the power sector, the markets for solar thermal collectors and geothermal heat pumps grew by 9%. bio-heat production remained stable in 2014, increasing only 1% from 2013 levels. The lack of infrastructure for heating systems and an uncertain policy environment impeded the development of the renewable energy renewable energy heating market (REN21-2015). The number of electric vehicles worldwide doubled year over year to 665,000. E-mobility and recent developments in battery storage (including significant cost reductions) are likely to change the future role of renewable energy in the transport sector. biofuels, however, are still the main renewable fuel source used in the transport sector and grew 8.4% in 2014 compared the previous year (REN21-2015). In conclusion, developments in the heating/cooling sector and the transport sector in particular are far too slow. Despite all the success in the renewable power sector, the extreme growth of coal power generation, especially in China, undercuts many successes with renewables. However, the first sign of a stagnation of coal demand in China – even a small decline for the first time in 2014 – provides reason to hope. The political framework of energy markets must adapt to the new emerging, mostly distributed energy technologies in order to support the transition to 100% renewable energy supply. Thus, Energy [R]evolution has begun, especially in the power sector, but heating and transport significantly lag behind. Overall, the transition from fossil and nuclear fuels to renewables is too slow, and energy demand is still growing too quickly. references 1 2

energy

[r]evolution

3.2 setting up an energy [r]evolution scenario

3.3 the energy [r]evolution logic

This section explains the basic principles and strategic approach of the development of the Energy [R]evolution concepts, which have served as a basis for the scenario modelling since the very first Energy [R]evolution scenario published in 2005. The Energy [R]evolution scenario series follows a “seven-step logic,” which stretches from the evaluation of natural resource limits to key drivers for energy demand and energy efficiency potentials, an analysis of available technologies and their market development potential, and specific policy measures required to implement a theoretical concept on real markets. This concept, however, has been constantly improved as technologies develop and new technical and economical possibilities emerge.

define natural limits for the climate and fuel resources.

define renewable energy resource limits.

identify drivers for demand.

define efficiency potentials by sector.

establish time lines for implementation.

identify required infrastructure.

identify required policies.

One of the major changes we have made in the Energy [R]evolution concept over the past years is to give solar photovoltaics a significantly increasing role in the energy sector and electric mobility a more important role due to better battery technology. both solar Pv and storage technologies are potentially disruptive; they could turn the energy sector on its head a relatively quickly.

define natural limits: the phase-out cascade for fossil fuels: Geological resources of coal could provide several hundred years of fuel, but we cannot burn them and keep within safe climate change limits. Thus, lignite – as the most carbon intensive coal – must be phased-out first, followed by hard coal. The use of oil will be phased-out in the pace of production depletion of existing oil wells (see chapter 5), and no new deep sea and Arctic / Antarctic oil wells will be opened. Gas production follows the same logic as oil and will be phased out as the last fossil fuel. reduce energy-related carbon dioxide to zero by mid-century: There is only so much carbon that the atmosphere can absorb. Each year we emit almost 30 billion tonnes of carbon equivalents. The Energy [R]evolution scenario has a target to phase-out energy-related CO 2 emissions by 2050. In addition, the regional transition towards carbon-free energy supply aims to achieve energy equity – shifting towards a fairer worldwide distribution of efficiently-used supply – as soon as technically possible. by 2040, the average per capita emission should be between 0.5 and 1 tonne of CO 2.

the seven steps are:

define renewable energy resource limits: renewable energy resource – mapping the future energy mix: The 5 renewable energy resources (solar, wind, hydro, geothermal and ocean) are available in different quantities – both by region and by season. Specific renewable energy potential maps are available from a number of scientific research institutions for each country around the world. The German Aerospace Centre takes part in the global mapping project of the International Renewable Energy Agency (IRENA), which provides detailed data for all renewable energy resources (IRENA-Global Atlas 2015). 4 The various regional renewable energy resources influence the projected energy mix in Energy [R]evolution scenarios. bioenergy – an important resource with limited sustainable potential: bioenergy is needed for fossil fuel replacement where no other technical alternative is available. Energy [R]evolution scenarios use bioenergy especially for industrial process heat, aviation, shipping and heavy machinery. Greenpeace identified the sustainable bioenergy potential globally in a scientific survey in 2008 at around 80 to maximum 100 Ej per year (Dbfz 2008).5 The overall sustainable bioenergy potential is, however, subject to change due to technical and scientific development and / or change of usage. An increased use of biomass for plastics, for example, would reduce the resources available for energy conversion.

references 4 5

(IRENA-GLObAL ATLAS 2015) GLObAL ATLAS fOR RENEWAbLE ENERGy; INTERNATIONAL RENEWAbLE ENERGy AGENCy (IRENA); Abu DHAbI /uAE; bONN/GERMANy; HTTP://IRENA.MASDAR.AC.AE/#; juLy 2015. (Dbfz 2008); GLObAL bIOMASS POTENTIALS – INvESTIGATION AND ASSESSMENT Of DATA – REMOTE SENSING IN bIOMASS POTENTIAL RESEARCH – COuNTRy SPECIfIC ENERGy CROP POTENTIAL; SEIDENbERGER ET. AL; DEuTSCHES bIOMASSEfORSCHuNGSzENTRuM; LEIPzIG/GERMANy, juNE 2008.

world energy [r]evolution a sustainable world energy outlook

identify drivers for demand:

equity and fair access to energy for all: The global and regional population development pathways are taken from united Nations projections (uN 2014). 6 Greenpeace does neither undertake any of its own population projections, nor is family planning part of the Energy [R]evolution energy scenario efficiency concept. However, a focus for future energy demand projections lies on a fair distribution of benefits and costs within societies, between nations, and between present and future generations. At one extreme, a third of the world’s population has no access to electricity, whilst the most industrialised countries consume much more than their fair share. The Energy [R]evolution concept aims to supply energy for an equal living standard for every person by 2050 if required economic development is believed to take place. (for further information, see chapter 5.)

smart grids are key, as is solar and wind power integration: Increased shares of distributed solar photovoltaic and onshore wind in distribution and medium voltage grids and offshore wind and concentrated solar power generation connected to transmission grids require the development of infrastructure, both for the physical setup and for management (brown et. al. 2014). 9 Also, the distribution of generation capacities across different voltage levels has a significant influence on required grid expansion and/or dispatch capacities (Teske 2015). 10 Existing gas pipelines and storage facilities might be available for the transport and storage of renewable hydrogen and/or methane. Existing gas power plants can therefore be used as dispatch plants to avoid stranded investments. storage – the next big thing: The development of electric vehicles has triggered more research in storage technologies, especially batteries. Increased shares of wind and solar caused another wave of research and market development for storage technologies, such as hydrogen, renewable methane and pumped hydro power plants. Storage technologies have thus improved significantly. Energy [R]evolution scenarios, however, aim to minimize storage needs for the next decade as costs are expected to remain high for that time frame. In the medium to long term, storage technologies are needed especially to replace fossil fuels with electricity in the transport sector.

decouple growth from fossil fuel use: The projections for economic growth are based on the International Energy Agencies (IEA) World Energy Outlook projections (for further information, see chapter 5). Starting in the developed countries, economic growth must be fully decoupled from fossil fuel usage. It is a fallacy to suggest that economic growth must be predicated on increased fossil fuel combustion.

define efficiency potentials by sector: energy not used is the cheapest; smart use of energy needed: Electrical appliances, industrial process, heating and cooling of buildings, and all forms of transport technologies still have significant efficiency potential. The latest available technologies in all sectors are implemented within the range of normal replacement rates. Energy [R]evolution scenarios focus on efficiency rather than sufficiency in the power and heating/cooling sector. The transport sector requires sufficiency especially in regard to usage of individual cars and aviation. A modular shift from road to rail and from air to rail where ever possible as an example of sufficiency.

identify required infrastructure:

identify required policies: new energy markets need new energy policies: Climate and energy policy need to go hand in hand. The uNfCCC process (see chapter 1) is key to protect the global climate, just as national energy policies are key to implement the required emission reduction with renewables and energy efficiency. The Energy [R]evolution scenarios are based on the experience documented in policy analysis, such as from REN 21 (REN21), 11 IRENA (IRENA 2015) 12 and the IEA (IEA 2015 A). Specific policy recommendations are documented in chapter 2 of this report.

establish time lines for implementation: there is no renewable energy shortage as such: The sun sends more energy to the earth surface per day than we consume each year. However, renewable energy technologies need to be engineered, installed, and operated, which requires skilled labour, financial resources and adapted energy policies. The transition from a fossil to a largely renewable energy supply system will take time. Energy [R]evolution scenarios take past experiences into account in determining how fast renewable energy technologies can scale up. In particular, the experience of Denmark, Germany and China during the last decade showed that a certain time is needed to train workers and set up required industries and infrastructure. An overheated renewable industry with low-quality products does more damage than good to a long-term transition. Thus, Energy [R]evolution scenarios are ambitious but not unrealistic. The first decade of our RE development pathways are based on industries projections such as from the Global Wind Energy Council (GWEC 2015)7 and Solar Power Europe (SPE 2015). 8

references 6 7 8 9

11 12

(uN 2014) ADD ExACT REfERENCE fOR POPuLATION PROjECTION. (GWEC 2015) GLObAL WIND REPORT: ANNuAL MARkET uPDATE; MARkET PROjECTION 2015 – 2019; bRuSSELS / bELGIuM; MAy 2015. (SPE 2015) GLObAL MARkET OuTLOOk fOR SOLAR POWER 2015 – 2019; SOLAR POWER EuROPE; bRuSSELS / bELGIuM; MAy 2015. (bROWN ET. AL. 2014) OPTIMISING THE EuROPEAN TRANSMISSION SySTEM fOR 77% RENEWAbLES by 2030; TOM bROWN, PETER-PHILIPP SCHIERHORN, ECkEHARD TR¨OSTER, THOMAS ACkERMANN; ENERGyNAuTICS GMbH, RObERT-bOSCHSTRASSE 7, 64293 DARMSTADT, GERMANy. (TESkE 2015); bRIDGING THE GAP bETWEEN ENERGy- AND GRID MODELS - DEvELOPING AN INTEGRATED INfRASTRuCTuRAL PLANNING MODEL fOR 100% RENEWAbLE ENERGy SySTEMS IN ORDER TO OPTIMIzE THE INTERACTION Of fLExIbLE POWER GENERATION, SMART GRIDS AND STORAGE TECHNOLOGIES; DISSERTATION; EuROPA uNIvERSITäT fLENSbuRG/GERMANy, SvEN TESkE DR. RER POL ; DIPL.-ING.; juNE 2015. (REN21-2015); RENEWAbLES 2015 GLObAL STATuS REPORT, PARIS: CH. 4; REN21 SECRETARIAT; WWW.REN21.NET; ISbN 978-3-9815934-6-4. (IRENA 2015 A) RENEWAbLE ENERGy TARGET SETTING, INTERNATIONAL RENEWAbLE ENERGy AGENCy; juNE 2015, HTTP://WWW.IRENA.ORG/DOCuMENTDOWNLOADS/PubLICATIONS/IRENA_RE_TARGET_SETTING_2015.PDf

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[r]evolution

3.4 the “5 step implementation” In 2013, renewable energy sources accounted for 19% of the world’s final energy demand. Modern renewables, such as solar, wind and geothermal energy, accounted for 10%, while traditional biomass contributed 9%. The latter often causes environmental damage and thus need to be replaced with new renewables as well. The share of renewable energy in electricity generation was 22.8% in 2013, a 5% increase over the past 4 years. About 78% of primary energy supply today still comes from fossil fuels13 - a decrease of 3 % over the past 4 years. Now is the time to make substantial structural changes in the energy and power sector within the next decade. Many power plants in industrialised countries, such as the uSA, japan and the European union, are nearing retirement; more than half of all operating power plants are over 20 years old. At the same time developing countries, such as China, India, South Africa and brazil, are looking to satisfy the growing energy demand created by their expanding economies. Worldwide, there is good news: Pv and wind are growing strongly. In 2015, roughly 50 GW of solar is expected to be installed, up from 30 GW annually at the beginning of this decade. This year, the global Pv market also crossed the 200 GW threshold. by the end of the decade, nearly half that much could be installed annually. Likewise, after years of roughly 3040 GW of annual additions, the wind market grew in 2014 by over 50 GW and will cross the 400 GW threshold this year. This market as well could grow to around 90 GW annually by the end of this decade. because the capacity factors of wind

turbines are generally double that of Pv, twice as much wind power would be generated from these additions. Within this decade, the power sector will decide how new electricity demand will be met, either by fossil and nuclear fuels or by the efficient use of renewable energy. The Energy [R]evolution scenario puts forwards a policy and technical model for renewable energy and cogeneration combined with energy efficiency to meet the world’s needs. Renewable energy and cogeneration – both as central-station power plants and distributed units – have to grow faster than overall global energy demand. both approaches must replace old generating technologies and deliver the additional energy required in the developing world. A transitional phase is required to build up the necessary infrastructure because it is not possible to switch directly from a large-scale fossil and nuclear energy system to a fully renewable energy supply. Whilst remaining firmly committed to the promotion of renewable sources of energy, we appreciate that conventional natural gas, used in appropriately scaled cogeneration plants, is valuable as a transition fuel, and can also drive cost-effective decentralisation of the energy infrastructure. With warmer summers, tri-generation – which incorporates heat-fired absorption chillers to deliver cooling capacity in addition to heat and power – will become a valuable means of achieving emissions reductions. The Energy [R]evolution envisages a development pathway away from the present energy supply structure and towards a sustainable system. There are three main stages to this.

figure 3.1 | estimated renewable energy share of global final energy consumption 2013

FOSSIL FUELS RENEWABLE ENERGY

78.3%

MODERN RENEWABLES HYDROPOWER

10.1%

19.1%

9% TRADITIONAL BIOMASS

3.9% 0.8% 4.1% 1.3%

BIOFUELS WIND, SOLAR, BIOMASS, GEOTHERMAL POWER BIOMASS, GEOTHERMAL, SOLAR HEAT

2.6% NUCLEAR POWER

source REN21-2015.

references 13

‘IEA WORLD ENERGy OuTLOOk 2014, PARIS NOvEMbER 2014.

world energy [r]evolution a sustainable world energy outlook

step 1: energy efficiency and equity

The Energy [R]evolution requires an ambitious exploitation of energy efficiency. The focus is on current best practices and products, along with probable future technologies, assuming continuous innovation. The energy savings are fairly equally distributed over the three sectors – industry, transport and domestic/business. Intelligent use, not abstinence, is the basic philosophy. The most important energy saving options are improved heat insulation and building design, super-efficient electrical machines and drives, replacement of old style electrical heating systems by renewable heat production (such as solar collectors) and a reduction in energy consumption by vehicles used for goods and passenger traffic. by the end of this decade, new buildings in Europe will have to be “nearly zero-carbon,” which is an excellent step forwards, though it comes a bit late – Passive House architecture was proven two decades ago. This energyefficient architecture can be used worldwide in almost all climates, both to reduce heating demand (such as in southern Canadian cities) as well as cooling demand (from Las vegas to Dubai). However, the greatest gains are to be made not in new buildings, but in renovations. Here, governments must speed up the renovation rate of existing building stock, and all renovations must be ambitious in light of long building service lives. Moreover, the comfort gains from such architecture make these buildings a pleasure to live and work in; here, intelligent energy use is clearly about better living, not abstinence.

Industrialised countries currently use energy most inefficiently. They can reduce their consumption drastically without losing either housing comfort or gadgets. The Energy [R]evolution scenario depends on OECD countries to save energy as developing countries increase theirs. The ultimate goal is stable global energy consumption within the next two decades. Another aim is to ‘energy equity’. A dramatic reduction in primary energy demand compared to the Reference scenario – but with the same GDP and population development - is a crucial prerequisite for achieving a significant share of renewable energy sources in the overall energy supply, compensating for the phasing out of nuclear energy and reduction in fossil fuel consumption. step 2: the renewable energy revolution decentralised energy and large scale renewables

Decentralised energy is connected to a local distribution network system, to which homes, offices, and small businesses are generally connected. Energy [R]evolution scenarios make extensive use of Distributed Energy (DE): energy generated at or near the point of use. We define distributed power generation as applications connected to low-and medium-voltage power lines with an average transport distance from several hundred meters up to around 100 kilometres. Several different distributed power plant technologies are available: solar photovoltaics, onshore wind turbines, run-of-river hydro power plants, bioenergy and geothermal power plants, and potentially near-shore ocean energy plants.

energy

[r]evolution

The dominant renewable electricity source is now wind power, but photovoltaics will catch up in the future. Significant cost reduction of solar photovoltaic roof-top systems is leading to “grid parity” in almost all industrialized countries. Households and small businesses can then produce their own solar power for the same or a lower cost than rates for grid electricity; onsite power generation - a term usually used for industry - now makes economic sense for the private sector. Distributed energy also includes stand-alone systems for heating / cooling either connected to district heating networks or for a single building supply, such as solar thermal collectors, bio energy heat systems and (geothermal) heat pumps. A hybrid between renewables and energy efficiency, heat pumps convert one unit of electricity into up to 4 units of heat. All these decentralized technologies can be commercialised for domestic users to provide sustainable, low-carbon energy. Increased shares of distributed generation technologies require adapted energy policies for “prosumers” – consumers who produce own energy. This option opens up a whole new market for solar photovoltaics and turns the business model for utilities on its head (see new business models). Those who were once captive utility customers will become utility competitors. Energy [R]evolution scenarios assume that private consumer and small and medium enterprises (SME) will meet most of

their electricity needs with solar photovoltaic and storage if space to set up the system is accessible. Therefore, utilities will lose most of their customers connected to the distribution grid until 2030 for electricity sales from centralized power plants. Therefore, utilities will have to move from selling energy to selling energy services by managing the operation and dispatch of decentralized generation capacity. Industry and business can use cogeneration power plants and co-generation batteries for on-site power generation to cover their own power needs. Surplus power will be sold to the grid, while excess heat can to be piped to nearby buildings, a system known as combined heat and power. for a fuel like (bio-) gas, almost all the input energy is used, not just a fraction as with traditional central-station fossil fuel electricity plants. While a large proportion of global energy in 2050 will be produced by decentralised energy sources, large-scale renewable energy will still be needed for an energy revolution. Large offshore wind farms and concentrating solar power (CSP) plants in the Sunbelt regions of the world will therefore have an important but broader role to play. Offshore wind turbines produce electricity more hours of the day, thereby reducing the need for backup generators, and CSP with storage is dispatchable. Centralized renewable energy will also be needed to provide process heat for industry and desalination (in the case of CSP), to supply increase power demand for the heating and transport sector, and to produce synthetic fuels for the transport sector.

figure 3.2 | a decentralised energy future ExISTING TECHNOLOGIES, APPLIED IN A DECENTRALISED WAy AND COMbINED WITH EffICIENCy MEASuRES AND zERO EMISSION DEvELOPMENTS, CAN DELIvER LOW CARbON COMMuNITIES AS ILLuSTRATED HERE. POWER IS GENERATED uSING EffICIENT COGENERATION TECHNOLOGIES PRODuCING bOTH HEAT (AND SOMETIMES COOLING) PLuS ELECTRICITy, DISTRIbuTED vIA LOCAL NETWORkS. THIS SuPPLEMENTS THE ENERGy PRODuCED fROM buILDING INTEGRATED GENERATION. ENERGy SOLuTIONS COME fROM LOCAL OPPORTuNITIES AT bOTH A SMALL AND COMMuNITy SCALE. THE TOWN SHOWN HERE MAkES uSE Of – AMONG OTHERS – WIND, bIOMASS AND HyDRO RESOuRCES. NATuRAL GAS, WHERE NEEDED, CAN bE DEPLOyED IN A HIGHLy EffICIENT MANNER. 5

1. photovoltaic, solar façades WILL bE A DECORATIvE ELEMENT ON OffICE AND APARTMENT buILDINGS. PHOTOvOLTAIC SySTEMS WILL bECOME MORE COMPETITIvE AND IMPROvED DESIGN WILL ENAbLE ARCHITECTS TO uSE THEM MORE WIDELy. 2. renovation can cut energy consumption of old buildings by AS MuCH AS 80% - WITH IMPROvED HEAT INSuLATION, INSuLATED WINDOWS AND MODERN vENTILATION SySTEMS.

3. solar thermal collectors PRODuCE HOT WATER fOR bOTH THEIR OWN AND NEIGHbOuRING buILDINGS. 4. efficient thermal power (chp) stations WILL COME IN A vARIETy Of SIzES - fITTING THE CELLAR Of A DETACHED HOuSE OR SuPPLyING WHOLE buILDING COMPLExES OR APARTMENT bLOCkS WITH POWER AND WARMTH WITHOuT LOSSES IN TRANSMISSION. 5. clean electricity fOR THE CITIES WILL ALSO COME fROM fARTHER AfIELD. OffSHORE WIND PARkS AND SOLAR POWER STATIONS IN DESERTS HAvE ENORMOuS POTENTIAL.

source GREENPEACE ENERGy [R]EvOLuTION 2012.

world energy [r]evolution a sustainable world energy outlook

step 3: the transport revolution moving around with different technologies and less energy

Switching to 100% renewables is most challenging in the transport sector. Today 92% of the transport energy comes from oil and only 1% from electricity (IEA 2015 b). 14 A simple “fuel switch” from oil to bio energy and electricity is neither technically possible nor sustainable. While there is an urgent need to expand electric mobility – public and individual transport technologies such as trains, busses, cars, and trucks – we also need to re-think our current mobility concept as such. The design of (mega-) cities has a huge influence whether people have to commute long distances or if they can walk or bike to work (WfC 2014). 15 On the other hand, increasing urban populations offer an opportunity to increase the usage of environmentally friendly mass transit systems. The transport of freight needs to move from road to rail and – if possible – from aviation to ships, which requires better logistics and new, more efficiency transport technologies (see chapter 12). Cars evolve in Energy [R]evolution scenarios. All potentials to make cars lighter and the combustion engine more efficient are exploited first. by around 2025, the car market moves via hybrid drives towards fully electric drives. The e-vehicle market is still nascent in 2015, and technical uncertainties remain, especially in regard to the storage technologies. We

therefore do not expect a real turnaround with significant oil reduction effect before 2025. However the technical evolution must start now in order to be ready by then. The use of biofuels is limited by the availability of sustainably grown biomass. It will primarily be committed to heavy machinery, aviation and shipping, where electricity does not seem to be an option for the next few decades. Outside the transport sector, biomass is needed for specific industries to supply process heat and carbon – not to mention as a raw material outside the energy sector. unlike previous Energy [R]evolution scenarios, this one no longer includes biofuels for private cars. 16 Electric vehicles will therefore play an even more important role in improving energy efficiency in transport and substituting for fossil fuels after 2025. Overall, achieving an economically attractive growth of renewable energy sources requires a balanced and timely mobilisation of all technologies. Such a mobilisation depends on resource availability, cost reduction potential and technological maturity. And alongside technology driven solutions, lifestyle changes - like simply driving less and using more public transport – have a huge potential to reduce greenhouse gas emissions. fortunately, these new behaviour patterns will be perceived as improvements, not compromises; young people around the world already increasingly prefer to spend time on their smart phones and buses and trains rather than drive.

references 14 15 16

(IEA 2015 b) ENERGy AND CLIMATE CHANGE – WORLD ENERGy OuTLOOk SPECIAL REPORT; INTERNATIONAL RENEWAbLE ENERGy AGENCy; MAy 2015. (WfC 2014); REGENERATIvE CITIES – COMMISSION ON CITIES AND CLIMATE CHANGE; HAfEN CITy uNIvERSITy, WORLD fTuRE COuNCIL; SEPTEMbER 2014. SEE CHAPTER 12.

energy

[r]evolution

step 4: smart infrastructure to secure renewables 24/7

• survive extreme situations such as sudden interruptions of

because renewable energy relies mostly on natural resources, which are not available at all times, some critics say this makes it unsuitable for large portions of energy demand. yet, Denmark got around 40 percent of its electricity from wind power alone in 2014; Spain and Portugal, around a quarter. A complete transformation of the energy system will be necessary to accommodate the significantly higher shares of renewable energy expected under the Energy [R]evolution scenario. The grid network of cables and substations that brings electricity to our homes and factories was designed for large, centralised generators running at huge loads, providing ‘base load’ power. until now, renewable energy has been seen as an additional slice of the energy mix and had had to adapt to the grid’s operating conditions. If the Energy Revolution scenario is to be realised, this situation will have to change.

supply (such as a fault at a generation unit) or interruption of the transmission system.

Renewable energy supply 24/7 is technically and economically possible; it just needs the right policy and the commercial investment to get things moving and ‘keep the lights on’ (GP-EN 2014). 17 The task of integrating renewable energy technologies into existing power systems is similar in all power systems around the world, whether they are large, centralized systems or island systems. Thorough planning is needed to ensure that the available production can match demand at all times. In addition to balancing supply and demand, the power system must also be able to: • fulfil defined power quality standards – voltage/frequency – which may require additional technical equipment in the power system and support from different ancillary services (see appendix 1 for definitions of terms); and

base load and system balancing

Power balance aims at keeping frequency in the system consistent. The mains frequency describes the frequency at which AC electricity is delivered from the generator to the end user, and it is measured in hertz (Hz). frequency varies in a system as the load (demand) changes. In a power grid operating close to its peak capacity, there can be rapid fluctuations in frequency, and dramatic fluctuations can occur just before a major power outage. Typically, power systems were designed around large power stations providing baseload capacity operating almost constantly at full output. These centralized units, typically nuclear or coal power plants, are inflexible generation resources – they don’t “follow load” – change their output to match changing demand – as well as flexible gas turbines and hydropower units, for instance. Power systems with large amounts of inflexible generation resources, such as nuclear power stations, also require a significant amount of flexible generation resources. priority dispatch for renewables ends “base-generation”

Renewable energy integrated into a smart grid changes the need for base load power. An energy switch based on renewables redefines the need for “base load” power generation. Instead, traditional base load power plants such as coal are replaced by a mix of flexible energy providers that can follow the load during the day and night (such as solar plus gas, geothermal, wind and demand management), without blackouts. The base load is therefore provided by a cascade of flexible power plants – instead of just baseload generation.

figure 3.3 | the evolving approach to grids. Current suPPly system: LOAD CURVE

LOW SHARES Of fLuCTuATING RENEWAbLE ENERGy

•

THE ‘bASE LOAD’ POWER IS A SOLID bAR AT THE bOTTOM Of THE GRAPH.

•

RENEWAbLE ENERGy fORMS A ‘vARIAbLE’ LAyER bECAuSE SuN AND WIND LEvELS CHANGES THROuGHOuT THE DAy.

•

GAS AND HyDRO POWER CAN bE SWITCHED ON AND Off IN RESPONSE TO DEMAND. THIS COMbINATION IS SuSTAINAbLE uSING WEATHER fORECASTING AND CLEvER GRID MANAGEMENT.

•

WITH THIS ARRANGEMENT THERE IS ROOM fOR AbOuT RENEWAbLE ENERGy.

to combat climate change much more than electricity is needed.

‘FLEXIBLE POWER’ GRID

•

OPERATOR COMBINES GAS AND HYDRO

FLUCTUATING RE POWER

PERCENT vARIAbLE

BASELOAD

percent renewable

0100

0600

1200

1800

2400

TIME OF DAY (HOUR)

source GREENPEACE ENERGy [R]EvOLuTION 2012.

references 17

(GP-EN 2014) POWE[R] 2030 -. A EuROPEAN GRID fOR 3/4 RENEWAbLE ELECTRICITy by 2030; GREENPEACE INTERNATIONAL / ENERGyNAuTICS; MARCH 2014.

world energy [r]evolution a sustainable world energy outlook

3 figure 3.5 | the evolving approach to grids. continued. suPPly system with more than 25 PerCent fluCtuating renewable energy > base load Priority: THIS APPROACH ADDS RENEWAbLE ENERGy buT GIvES PRIORITy TO bASE LOAD

•

AS RENEWAbLE ENERGy SuPPLIES GROW THEy WILL ExCEED THE DEMAND AT SOME TIMES Of THE DAy, CREATING SuRPLuS POWER.

•

TO A POINT, THIS CAN bE OvERCOME by STORING POWER, MOvING POWER bETWEEN AREAS, SHIfTING DEMAND DuRING THE DAy OR SHuTTING DOWN THE RENEWAbLE GENERATORS AT PEAk TIMES.

SURPLUS RENEWABLE ENERGY: SEE OPTIONS BELOW

LOAD CURVE

•

BASELOAD PRIORITY: NO CURTAILMENT OF COAL OR NUCLEAR POWER

this approach does not work when renewables exceed 50 percent of the mix, and cannot provide renewable energy as 90- 100% of the mix.

BASELOAD

0100

0600

1200

1800

2400

TIME OF DAY (HOUR)

suPPly system with more than 25 PerCent fluCtuating renewable energy – renewable energy Priority THIS APPROACH ADDS RENEWAbLES buT GIvES PRIORITy TO CLEAN ENERGy.

•

If RENEWAbLE ENERGy IS GIvEN PRIORITy TO THE GRID, IT “CuTS INTO” THE bASE LOAD POWER.

•

THEORETICALLy, NuCLEAR AND COAL NEED TO RuN AT REDuCED CAPACITy OR bE ENTIRELy TuRNED Off IN PEAk SuPPLy TIMES (vERy SuNNy OR WINDy).

•

THERE ARE TECHNICAL AND SAfETy LIMITATIONS TO THE SPEED, SCALE AND fREQuENCy Of CHANGES IN POWER OuTPuT fOR NuCLEAR AND CCS COAL PLANTS.

LOAD CURVE RE PRIORITY: CURTAILMENT OF BASELOAD POWER TECHNICALLY DIFFICULT IF NOT IMPOSSIBLE

•

technically difficult, not a solution. 0100

0600

1200

1800

2400

TIME OF DAY (HOUR)

the solution: an oPtimised system with over 90% renewable energy suPPly

•

DEMAND MANAGEMENT EffECTIvELy MOvES THE HIGHEST PEAk AND ‘fLATTENS OuT’ THE CuRvE Of ELECTRICITy uSE OvER A DAy.

(OPTION 1 & 2)

LOAD CURVE WITH NO DSM

A fuLLy OPTIMISED GRID, WHERE 100 PERCENT RENEWAbLES OPERATE WITH STORAGE, TRANSMISSION Of ELECTRICITy TO OTHER REGIONS, DEMAND MANAGEMENT AND CuRTAILMENT ONLy WHEN REQuIRED.

PV BIOENERGY, HYDRO, CSP & GEOTHERMAL WIND

•

RE POWER IMPORTED FROM OTHER REGIONS & RE POWER FROM STORAGE PLANTS

LOAD CURVE WITH DSM

SUPPLY: WIND + SOLAR

works!

0100

0600

1200 TIME OF DAY (HOUR)

source

DR. SvEN TESkE

GREENPEACE

- 2015.

1800

2400

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[r]evolution

the smart-grid vision for the energy [r]evolution

step 5: new policies to enable new business models

Developing a power system based almost entirely on renewable energy sources will require a new overall power system architecture – including Smart-Grid Technology, which will need substantial amounts of work to emerge (ECOGRID). 18 figure 3.6 shows a very basic graphic representation of the key elements of future, renewable-based power systems using Smart Grid technology (GP-EN 2009). 19

The Energy Revolution scenario will also result in a dramatic change in the business model of energy companies, utilities, fuel suppliers and manufacturers of energy technologies. Decentralised energy generation for self-supply along with utility-scale solar, onshore and offshore wind farms in remote areas will have a profound impact on the way utilities operate by 2020. for instance, these energy sources require no fuel, which will challenge vertically integrated utilities.

figure 3.4 | the smart-grid vision for the energy [r]evolution a vision for the future – a network of integrated Microgrids that can Monitor and heal itself WIND fARM 7

CENTRAL POWER PLANT 7

1 2

OffICES WITH SOLAR PANELS

2 1

6 1

2 7

SMART HOMES

SOLAR PARk

2 7

3 5

ISOLATED 4 MICROGRID

4 5

sensors (‘activated’)

ExECuTE SPECIAL PROTECTION SCHEMES IN MICROSECONDS

DETECT fLuCTuATIONS AND DISTuRbANCES, AND CAN SIGNAL fOR AREAS TO bE ISOLATED

sensors (on ‘standby’) DETECT fLuCTuATIONS AND DISTuRbANCES, AND CAN SIGNAL fOR AREAS TO bE ISOLATED

processors

INDuSTRIAL PLANT

disturbance IN THE GRID

smart appliances CAN SHuT Off IN RESPONSE TO fREQuENCy fLuCTuATIONS demand management uSE CAN bE SHIfTED TO Off PEAk TIMES TO SAvE MONEy

generators ENERGy fROM SMALL GENERATORS AND SOLAR PANELS CAN REDuCE OvERALL DEMAND ON THE GRID storage energy GENERATED AT Off-PEAk TIMES COuLD bE STORED IN bATTERIES fOR LATER uSE

source GREENPEACE ENERGy [R]EvOLuTION 2012.

references 18 19

SEE ALSO ECOGRID PHASE 1 SuMMARy REPORT, AvAILAbLE AT: HTTP://WWW.ENERGINET.Dk/NR/RDONLyRES/8b1A4A06CbA3-41DA-9402-b56C2C288fb0/0/ECOGRIDDk_PHASE1_SuMMARyREPORT.PDf (GP-EN 2009) EuROPEAN RENEWAbLE ENERGy COuNCIL/GREENPEACE REPORT, “[R]ENEWAbLES 24/7: INfRASTRuCTuRE NEEDED TO SAvE THE CLIMATE”, NOvEMbER 2009.

world energy [r]evolution a sustainable world energy outlook

The current model is a relatively small number of large power plants owned and operated by utilities or their subsidiaries, generating electricity for the population. under the Energy Revolution scenario, around 60 to 70% of electricity will be made by small but numerous distributed power plants. Ownership will shift away from centralised utilities towards more private investors, manufacturers of renewable energy technologies and EPC companies (engineering, procurement and construction). In turn, the value chain for power companies will shift towards project development, equipment manufacturing and operation and maintenance (figure 4). Simply selling electricity to customers will play a smaller role; power companies of the future will deliver a total power plant and the required IT services to customers, not just electricity. They will therefore move towards becoming service providers for customers. The majority of power plants will also not require any fuel supply, so fuel production companies will lose their strategic importance. Today’s power supply value chain is broken down into clearly defined players, but a global renewable power supply will inevitably change this division of roles and responsibilities. The following table provides an overview of how the value chain would change in a revolutionised energy mix.

The future pattern under the Energy [R]evolution will see more and more renewable energy companies, such as wind turbine manufacturers becoming involved in project development, installation, and operation and maintenance, whilst utilities will lose their status. Traditional energy supply companies that do not move towards renewable project development will either lose market share or drop out of the market completely. policy defines ownership and investment flows

In order to organize the transition towards a 100% renewable energy market, specific policies are required to provide planning and investment security for small and medium-size enterprises (SME). Those policies must first and foremost secure access to infrastructure – power lines, gas pipelines and district heating systems – so that electricity, hydrogen, renewable methane and/or renewable heat can be transported to customers. Priority dispatch in all networks is key for project developers and investors as well because the projected amount of renewable energy produced each year is a fundamental cornerstone for financial planning.

figure 3.5 | changing value chain for planning, construction and operation of new power plants

TASk & MARkET PLAyER CuRRENT SITuATION POWER MARkET

PROjECT DEvELOPMENT

MANufACTuRE Of GEN. EQuIPMENT

INSTALLATION

OWNER Of THE POWER PLANT

OPERATION & MAINTENANCE

fuEL SuPPLy

Coal, gas and nuclear power stations are larger than renewables. Average number of power plants needed per 1 GW installed only 1 or 2 projects.

Relatively view power plants owned and sometimes operated by utilities.

A few large multinational oil, gas and coal mining companies dominate: today approx 75-80% of power plants need fuel supply.

Renewable power plants are small in capacity, the amount of projects for project development, manufacturers and installation companies per installed 1 GW is bigger by an order of magnitude. In the case of Pv it could be up to 500 projects, for onshore wind still 25 to 50 projects.

Many projects will be owned by private households by 2050 almost all power or investment banks in the case of larger projects. generation technologies accept biomass - will operate without the need of fuel supply.

TRANSMISSION TO THE CuSTOMER

Grid operation will move towards state controlled grid companies or communities due to liberalisation.

market Player POWER PLANT ENGINEERING COMPANIES uTILITIES MINING COMPANIES GRID OPERATOR

2020 AND bEyOND POWER MARkET

market Player RENEWAbLE POWER PLANT ENGINEERING COMPANIES PRIvATE & PubLIC INvESTORS GRID OPERATOR source

DR. SvEN TESkE

GREENPEACE .

Grid operation will move towards state controlled grid companies or communities due to liberalisation.

energy

[r]evolution

future customer groups

The capacity demand of power and/or heat for different customer groups defines the voltage level they are connected to and whether they are connected to the distribution or transmission level of gas pipelines. The interface between customer and infrastructure opens a variety of technology and hence business options for energy service companies. for households with access to a roof space, for example, the installation of solar photovoltaics is now very often a leastcost option. The cost of photovoltaic electricity has decreased dramatically over the past few years. Parity with retail electricity and oil-based fuels has been reached in many countries and market segments and wholesale parity is approaching in some markets (beyer 2015). 20 figure 3.8 provides a rough overview of technology options for different customers groups with regard to their infrastructural needs.

This section only covers a small share of business model possibilities for utilities. However, it seems relatively clear that not changing the current conventional business model is not an option for utilities either. German utilities are a good example of future challenges. In 2014, RWE – one of Germany’s two biggest utilities along with Eon – posted a 45 percent drop in profits. Power prices are down, and the share of conventional electricity is also falling, so these firms sell less power at lower prices. At RWE, power sales fell by 7.5 percent in 2014 year over year, for instance. The result was 29 percent lower operating the profits from conventional power generation. The outlook is also dismal, with year-ahead prices dropping to the lowest level in a decade. RWE has responded partly by forming a partnership with EPC (Conergy) for significant investments in rooftop solar in Germany. Likewise, Eon is breaking up into two companies: one doing business with conventional energy, and the other with renewables and energy services. This plan is clear evidence that top utility experts understand the incompatibility of conventional energy with renewables. (Pv-M 3-2015). 21

references 20 21

(bEyER 2015) Pv LCOE IN EuROPE 2014-30; fINAL REPORT, juLy 2015; uNIvERSITy LAPPEENRANTA / fINLAND, DR. CHRISTIAN bREyER; Pv TECHNOLOGy PLATTfORM;WWW.EuPvPLATfORM.ORG (Pv-M 3-2015); Pv MAGAzINE, RWE PROfITS SLuMP AMID CRISIS IN CONvENTIONAL ENERGy; 10TH MARCH 2015; IAN CLOvER; HTTP://WWW.Pv-MAGAzINE.COM/NEWS/DETAILS/bEITRAG/RWE-PROfITS-SLuMP-AMID-CRISIS-IN-CONvENTIONALENERGy_100018539.

f i n a n c i n g t h e e n e r gy [ r ] e vo lu t i o n overcoming barriers to finance and investment for renewable energy

4 4

renewable energy financing basics

how to overcome investment barriers for renewable energy

the first decade of renewable energy financing

“

secure, predictable policies are key to financing the energy revolution”

renewable energy project planning basics

image rio MaMoré, brazil, 2014. the river flows toward the north (left in these iMages) and receives a large aMount of sediMent at the confluence with the rio grande. the extra sediMent enhances the growth of Point bars—the lighter-colored, vegetation-free areas along the inside bends of the riverbank. natural habitats that exist within floodPlains dePend on river Migration to both renew habitat and Maintain the natural functioning of existing habitat.

energy

[r]evolution

4.1 renewable energy project planning basics The renewable energy market works significantly different than coal, gas and nuclear power markets. The table below provides an overview of the ten steps from “field to an operating power plant” for renewable energy projects in the current market situation. Those steps are similar same for

each renewable energy technology; however, steps 3 and 4 are especially important for wind and solar projects. In developing countries, the government and mostly stateowned utilities might directly or indirectly act as project developers. The project developer might also be work as a subdivision of a state owned utility.

table 4.1 | how does the current renewable energy market work in practice?

STEP

WHAT WILL BE DONE?

WHO?

NEEDED INFORMATION / POLICY AND/OR INVESTMENT FRAMEWORK

step 1:

identify the best locations for generators (e.g. wind turbines) and pay special attention to technical and commercial data, conservation issues and any concerns that local communities may have.

resource analysis to identify possible sites

SITE IDENTIfICATION

Policy stability in order to make sure that the policy is still in place once step 10 has been reached. without a certainty that the renewable electricity produced can be fed entirely into the grid to a reliable tariff, the entire process will not start.

step 2: SECuRING LAND uNDER CIvIL LAW

step 3: DETERMINING SITE SPECIfIC POTENTIAL

secure suitable locations through purchase and lease agreements with land owners.

transparent planning, efficient authorisation and permitting.

site specific resource analysis (e.g. wind measurement on hub height) from independent experts. this will not be done by the project developer as (wind) data from independent experts is a requirement for risk assessments by investors.

P+M

see above.

step 4:

specialists develop the optimum configuration or sites for the P technology, taking a wide range of parameters into consideration in order to achieve the best performance.

step 5:

organise all necessary surveys, put together the required documentation and follow the whole permit process.

transparent planning, efficient authorisation and permitting.

electrical engineers work with grid operators to develop the optimum grid connection concept.

P+u

Priority access to the grid.

TECHNICAL PLANNING/ MICROSITING

PERMIT PROCESS

step 6: GRID CONNECTION PLANNING

step 7: fINANCING

step 8: CONSTRuCTION

certainty that the entire amount of electricity produced can be feed into the grid.

P+i once the entire project design is ready and the estimated annual output (in kwh/a) has been calculated, all permits are processed and the total finance concept (incl. total investment and profit estimation) has been developed, the project developer will contact financial institutions to either apply for a loan and/or sell the entire project. civil engineers organise the entire construction phase. this can be done by the project developer or another.

P+i

START Of OPERATION

step 10: buSINESS AND OPERATIONS MANAGEMENT

long term power purchase contract. Prior and mandatory access to the grid. site specific analysis (possible annual output).

signed contracts with grid operator. signed contract with investors.

ePc (engineering, procurement & construction) company – with the financial support from the investor. step 9:

see above.

electrical engineers make sure that the power plant will be connected to the power grid.

P+u

Prior access to the grid (to avoid curtailment).

optimum technical and commercial operation of power plants/farms throughout their entire operating life – for the owner (e.g. a bank).

P+u+i

good technology & knowledge (a cost-saving approach and “copy + paste engineering” will be more expensive in the long-term).

P ProJect develoPer. m Meteorological exPerts. i investor. u utility. source SWISS RE 2011.

world energy [r]evolution a sustainable world energy outlook

finance debt typically covers 70–90% of the cost of a project, is non-recourse to the investors, and ideally matches the duration of the underlying contractual agreements.

4.2 the impacts of climate change The Swiss RE Private Equity Partners have provided an introduction to renewable energy infrastructure investing (Swiss RE – 2011) 1 describing what makes renewable energy projects different from fossil-fuel based energy assets from a finance perspective: • Renewable energy projects have short construction period compared to conventional energy generation and other infrastructure assets. Renewable projects have limited ramp-up periods, and construction periods of one to three years, compared to 10 years to build while large conventional power plants. • In several countries, renewable energy producers have been granted priority dispatch. Where in place, grid operators are usually obliged to connect renewable power plants to their grid, and retailers or other authorised entities must purchase all renewable electricity produced. • Renewable projects present relatively low operational complexity compared to other energy generation assets and other infrastructure asset classes. Onshore wind and solar Pv projects in particular have well established operational track records. This is obviously less the case for biomass and offshore wind plants. • Renewable projects typically have non-recourse financing, through a mix of debt and equity. In contrast to traditional corporate lending, project finance relies on future cash flows for interest and debt repayment, rather than the asset value or the historical financial performance of a company. Project

• Renewable power typically has predictable cash flows and is not subject to fuel price volatility because the primary energy resource is generally free (except for biomass). Contractually guaranteed tariffs along with the moderate cost of building, operating and maintaining renewable generation facilities allow for secure profit margins and predictable cash flows. • Renewable electricity remuneration mechanisms often include some kind of inflation indexation, although incentive schemes may vary on a case-by-case basis. for example, several tariffs in the Eu are indexed to consumer price indices and adjusted on an annual basis (such as in Spain and Italy). In projects where specific inflation protection is not provided (such as in Germany), the regulatory framework allows selling power on the spot market, should the power price be higher than the guaranteed tariff. • Renewable power plants have expected long useful lives (over 20 years). Transmission lines usually have economic lives of over 40 years. Renewable assets are typically underpinned by long-term contracts with utilities and benefit from governmental support and manufacturer warranties. • Renewable energy projects deliver attractive and stable sources of income, only loosely linked to the economic cycle. Project owners do not have to manage fuel cost volatility, and projects generate high operating margins with relatively secure revenues and generally limited market risk.

figure 4.1 | return characteristics of renewable energies

short ConstruCtion Period

guaranteed Power disPatCh

non - reCourse finanCing

low oPerational ComPlexity

opportunites

power generation

transmission & storage

investors benefits predictable cash flows

inflation linkage

long duration

recurring income

source SWISS RE 2011. references 1

(SWISS RE 2011), AN INTRODuCTION TO RENEWAbLE ENERGy INfRASTRuCTuRE INvESTING; CONTACT: RObERT NEf; CO-HEAD INvESTOR SOLuTIONS; RObERT_NEf@SWISSRE.COM; +41 43 285 2121NEWAbLE ENERGy INfRASTRuCTuRE INvESTING - SWISS RE PRIvATE EQuITy PARTNERS; SEPTEMbER 2011;

energy

[r]evolution

• The widespread development of renewable power generation will require significant investments in the electricity grid. future grid (smart grids) will have to integrate an ever-increasing, decentralised, fluctuating supply of renewable energy. furthermore, suppliers and/or distribution companies will be expected to deliver a sophisticated range of services by embedding digital grid devices into power networks. Risk assessment and allocation is at the centre of project finance. Accordingly, project structuring and expected return are directly related to the risk profile of the project. The four main risk factors to consider when investing in renewable energy assets are:

figure 4.2 | overview risk factors for renewable energy projects

regulatory risks

ConstruCtion risks

finanCing risks

oPerational risks

source SWISS RE 2011.

figure 4.3 |

• Regulatory risks refer to adverse changes in laws and regulations, unfavourable tariff setting and changes in and breaches of contracts. However policy security is crucial for all forms of energies and a long-term energy policy stability is the basic fundament for all investments. However, a diversified investment across regulatory jurisdictions, geographies, and technologies can help mitigate those risks. • Construction risks relate to the delayed or costly delivery of an asset, the default of a contracting party, or an engineering/design failure. Construction risks are less prevalent for renewable energy projects because they have relatively simple designs; however, construction risks can be further mitigated by selecting high-quality and experienced turnkey partners, using proven technologies and established equipment suppliers, and agreeing on retentions and construction guarantees • Financing risks refer to the inadequate use of debt in the financial structure of an asset. Examples include the abusive use of leverage, exposure to interest rate volatility, and the need to refinance at less favourable terms. • Operational risks include equipment failure, counterparty default, and reduced availability of the primary energy source (such as wind, heat, and insolation). for renewable assets, lower than forecast resource availability will result in lower revenues and profitability, so this risk can detrimentally impact the business case.

investment stages of renewable energy projects

risks higher

lower stage

• • • •

site identifiCation aPProval

Permitting ProCess

land ProCurement teChniCal Planning

oPerations

ConstruCtion

develoPment

• • • • •

finanCing Close equiPment ProCurement engineering ConstruCtion

• • • •

oPerations maintenanCe refinanCing refurbishment/rePowering

Commissioning

strategy early- stage greenfield

late - stage greenfield

brownfield

source SWISS RE 2011.

world energy [r]evolution a sustainable world energy outlook

scale of development required. The key barriers to renewable energy investment identified by Greenpeace in a literature review 2 and interviews with renewable energy sector financiers and developers are shown in figure 4.4.

4.3 overcoming barriers to finance and investment for renewable energy

Despite the relatively strong growth in renewable energies in an increase number of countries, many barriers still hinder the rapid uptake of renewable energy needed to achieve the

table 4.2 | categorisation of barriers to renewable energy investment

Category

sCenario name

status quo

baseline

Category iii+iv (>440 600PPm)

Category i+ ii (< 440PPm)

IEA ETP

IEA WEO 2009 IEA WEO 2011

ReMind

MiniCam

E[R] 2010

E[R] 2012

ReMind

EMf22

MESAP/PlaNet

20xx

2010

2012

model

2015

year of PubliCation

2009

2011

2030

2050*

2030

2050*

all**

all

all**

all

CCs

(+)

nuClear

(+)

units

2030

2050

2030

2050

Category i+ ii (< 440PPm)

2030

2050

2030

2050

Pv and csP not differentiated, ocean energy not included

all

(+)

(-)

(+)

(-)

(+)

(-)

teChology Pathway (-) teChnology not inCluded (+) teChnology inCluded renewables

PoPulation gdP/CaPita**

bILLION

6.67

8.31

9.15

8.31

9.15

8.32

9.19

8.07

8.82

8.31

9.15

8.31

9.15

k$2005/CAPITA

17.4

24.3

12.4

18.2

9.7

13.9

17.4

24.3

Ej/y

568

645

749

694

805

590

674

608

690

474

407

526

481

Mj/$2005

4.5

3.4

5.7

4.0

7.8

5.6

3.3

1.8

GT CO2/y

32.2

38.5

44.3

39.2

45.3

26.6

15.8

29.9

12.4

18.4

3.7

20.1

3.1

57.1

56.6

45.0

23.5

49.2

18.0

36.7

7.1

energy demand (direCt equivalent) energy intensity renewable energy fossil

industrial Co2 emissions

Carbon intensity

Pv and csP not differentiated

CO2/Gj

* IEA (2009) does not cover the years 2031 till 2050. As the IEA’s projection only covers a time horizon up to 2030 for this scenario exercise, an extrapolation of the scenario has been used that was provided by the German Aerospace Agency (DLR) by extrapolating the key macroeconomic and energy indicators of WEO 2009 forward to 2050 (Teske et al., 2010c). ** The data are either input for the model or endogenous model results. *** Solar photovoltaics, Concentrated Solar Power, solar water heating, wind (on- and offshore), Geothermal power, heating and cogeneration, bioenergy power, heating and co-generation, hydro power, ocean energy.

s c e n a r i o r e s u lts global

oecd europe

eastern europe/eurasia

china oecd asia oceania

oecd north america

africa

india

latin america

middle east

other asia

“

100% re: energy supply without carbon and nuclear disastours”

image in June 2000, swarMs of earthquakes and a Massive volcanic eruPtion rocked MiyakeJiMa, a sMall JaPanese island about 180 kiloMeters (110 Miles) south of tokyo. by 2015, the island had a PoPulation of 2,775 residents. in Many resPects, life has returned to norMal. fishing, farMing, and tourisM are MiyakeJiMa’s PriMary industries. since oyaMa still Periodically eMits large aMounts of sulfur dioxide, residents and tourists are suPPosed to carry a gas Mask with theM at all tiMes. one third of the island reMains off liMits.

energy

[r]evolution

6.1 world 6.1 global scenario results

6.1.1 projection of energy intensity

The development of future global energy demand is determined by three key factors

An increase in economic activity and a growing population does not necessarily have to result in an equivalent increase in energy demand. There is still a large potential for exploiting energy efficiency measures. under the Reference scenario we assume that energy intensity will be reduced by 1.85% on average per year, leading to a reduction in final energy demand per unit of GDP of about 51% between 2012 and 2050. under the basic Energy [R]evolution scenario it is assumed that energy intensity decreases by 3.45 % while the Advanced Energy [R]evolution achieves minus 3.55 % per year due to active policy and technical support for energy efficiency measures and will lead to an even higher reduction in energy intensity of almost 75% until 2050.

• Population development: the number of people consuming energy or using energy services. • Economic development, for which Gross Domestic Product (GDP) is the most commonly used indicator: in general an increase in GDP triggers an increase in energy demand. • Energy intensity: how much energy is required to produce a unit of GDP. The Reference scenario and the Energy [R]evolution scenarios are based on the same projections of population and economic development. The future development of energy intensity, however, differs between the reference and the alternative cases, taking into account the measures to increase energy efficiency under both Energy [R]evolution scenarios.

figure 6.1.1 | global: final energy intensity under the reference and both energy [r]evolution scenarios

3.5

FINAL ENERGY INTENSITY [MJ/$GDP]

3.0

2.5

2.0

1.5

1.0

0.5

2010

2015

2020

2025

2030

2035

2040

2045

2050

REFERENCE SCENARIO ENERGY [R]EVOLUTION SCENARIO ADVANCED ENERGY [R]EVOLUTION SCENARIO

world energy [r]evolution a sustainable world energy outlook

This reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. The transformation to a carbon free energy system in the Advanced scenario will further increase the electricity demand in 2050 up to more than 40,000 TWh/a. Electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. Around 8,100 TWh are used in 2050 for electric vehicles and rail transport in the Advanced scenario, around 5,100 TWh for hydrogen and 3,600 TWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.1.2 final energy demand by sector

under both Energy [R]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.1.3). Total electricity demand will rise from about 18,860 TWh/a to 37,000 TWh/a by 2050 in the basic Energy [R]evolution scenario. Compared to the Reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 16,700 TWh/a.

Efficiency gains in the heating sector are even larger than in the electricity sector. under the Energy [R]evolution scenarios, consumption equivalent to about 76,000 Pj/a is avoided through efficiency gains by 2050 compared to the Reference scenario. As a result of energy-related renovation of the existing stock of residential buildings, the introduction of low energy standards and ‘passive climatisation’ for new buildings, as well as highly efficient air conditioning systems, enjoyment of the same comfort and energy services will be accompanied with much lower future energy demand.

figure 6.1.2 | global: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat froM chP autoProducers 600,000

500,000

400,000

PJ/a

Combining the projections on population development, GDP growth and energy intensity results in future development pathways for World’s final energy demand. These are shown in figure 6. for the Reference and Energy [R]evolution scenarios. under the Reference scenario, total final energy demand increases by 65% from the current 326,900 Pj/a to around 539,000 Pj/a in 2050. In the basic Energy [R]evolution scenario, final energy demand decreases by 12% compared to current consumption and is expected to reach 289,000 Pj/a by 2050. The Advanced scenario results in some additional reductions due to a higher share of electric cars.

300,000

200,000 EFFICIENCY

100,000

OTHER SECTORS INDUSTRY TRANSPORT

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.1.5 | global: development of final energy demand for heat by sector in the energy [r]evolution scenarios

figure 6.1.3 | global: development of electricity demand by sector in the energy [r]evolution scenarios

30,000

180,000 160,000

25,000

140,000 20,000

100,000

PJ/a

120,000

80,000

15,000

10,000

60,000 40,000

5,000

20,000 0

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.1.4 | global: development of the final energy demand for transport by sector in the energy [r]evolution scenarios 160,000 140,000 120,000

PJ/a

100,000 80,000 60,000 40,000 20,000 0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

world energy [r]evolution a sustainable world energy outlook

6.1.2 electricity generation

in gw

HyDRO

REf E[R] ADv

bIOMASS

REf E[R] ADv

WIND

REf E[R] ADv

GEOTHERMAL

REf E[R] ADv

A 100% electricity supply from renewable energy resources in the Advanced scenario leads to around 23,600 GW installed generation capacity in 2050.

REf E[R] ADv

CSP

Table 6.1.1 shows the comparative evolution of the different renewable technologies worldwide over time. up to 2020 wind and Pv will become the main contributors to the growing market share. After 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. The Energy [R]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 31% to 36% by 2030 and 53% to 55% by 2050. Therefore, smart grids, demand side management (DSM), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

REf E[R] ADv

OCEAN

REf E[R] ADv

total

ref e[r] adv

2012 1,099 1,099 1,099 87 87 87 277 277 277 11 11 11 97 97 97 3 3 3 0 0 0 1,575 1,575 1,575

2020 1,331 1,316 1,316 150 194 200 554 820 904 17 28 31 332 732 844 11 31 42 1 11 11 2,396 3,132 3,348

2030 1,544 1,397 1,402 199 392 405 807 2,510 3,064 28 137 171 494 2,839 3,725 26 405 635 4 95 131 3,101 7,774 9,532

2040 1,715 1,445 1,457 243 558 579 998 4,316 5,892 42 325 452 635 4,988 6,678 49 984 1,616 15 318 432 3,696 12,934 17,105

2050 1,878 1,503 1,536 293 746 742 1,217 5,575 8,040 62 485 708 803 6,745 9,295 74 1,473 2,555 28 552 738 4,355 17,079 23,614

figure 6.1.6 | global: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 80,000 OCEAN ENERGY

70,000

CSP

60,000

GEOTHERMAL BIOMASS

50,000 TWh/a

table 6.1.1 | global: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios

The development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. This trend will more than compensate for the phasing out of nuclear power production in the Energy [R]evolution scenarios, continuously reducing the number of fossil fuelfired power plants as well. by 2050, 92% of the electricity produced worldwide will come from renewable energy sources in the basic Energy [R]evolution scenario. ‘New’ renewables – mainly wind, Pv, CSP and geothermal energy – will contribute 68% to the total electricity generation. Already by 2020 the share of renewable electricity production will be 31% and 58% by 2030. The installed capacity of renewables will reach about 7,770 GW in 2030 and more than 17,000 GW by 2050.

PV WIND

40,000

HYDRO HYDROGEN

30,000

NUCLEAR DIESEL

20,000

OIL GAS

10,000

LIGNITE COAL

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.1.3 future costs of electricity generation

6.1.4 future investments in the power sector

figure 6.1.7 shows that the introduction of renewable technologies under both Energy [R]evolution scenarios increases the future costs of electricity generation compared to the Reference scenario until 2030. This difference in full cost of generation will be less than 0.2 uS$ct/kWh in both Energy [R]evolution scenarios, without taking into account integration costs for storage or other load-balancing measures. because of increasing prices for conventional fuels, electricity generation costs will become economically favourable starting in 2030 under the Energy [R]evolution scenarios. by 2050, the cost will be 2.5/1.7 uS$ct/kWh, respectively, below those in the Reference case.

Around uS$ 48,000 billion is required in investment for the Energy [R]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately uS$ 1,233 billion per year, around uS$ 23,500 billion more than in the Reference scenario (uS$ 24,500 billion). Investments for the Advanced scenario add up to uS$ 64,600 billion until 2050, on average uS$ 1,656 billion per year, including high investments in additional power plants for the production of synthetic fuels. under the Reference scenario, the levels of investment in conventional power plants add up to almost 50% while approximately 50% would be invested in renewable energies and cogeneration until 2050.

under the Reference scenario, on the other hand, growth in demand and increasing fossil fuel prices result in total electricity supply costs rising from todayâ&#x20AC;&#x2122;s uS$ 2,063 billion per year to more than uS$ 5,400 billion in 2050, compared to uS$ 4,300 billion in the basic and uS$ 6,200 billion in the Advanced Energy [R]evolution scenario. figure 6.1.7 shows that both Energy [R]evolution scenarios not only comply with WorldÂ´s CO 2 reduction targets, but also help stabilise energy costs and relieve the economic pressure on society. Increasing energy efficiency and shifting energy supply to renewables lead to long term costs for electricity supply that are more than 19% lower in the basic Energy [R]evolution scenario than in the Reference scenario. The Advanced scenario with 100% renewable power and an increase in power generation of 35% results in supply costs 16% higher than the Reference case.

figure 6.1.7 | global: development of total electricity supply costs & of specific electricity generation costs in the scenarios Billion $

under the Energy [R]evolution scenarios, however, World would shift almost 93%/94% of the entire investment towards renewables and cogeneration, respectively. by 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants. because renewable energy has no fuel costs, the fuel cost savings in the basic Energy [R]evolution scenario reach a total of more than uS$ 39,000 billion up to 2050, around uS$ 1,000 billion per year. The total fuel cost savings therefore would cover 170% of the total additional investments compared to the Reference scenario. fuel cost savings in the Advanced scenario are even higher and add up to uS$ 42,000 billion, or uS$ 1,080 billion per year. Renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.1.8 | global: investment shares reference versus energy [r]evolution scenarios

US$ct/kWh

8,000

FOSSIL,

7,000

39% 42%

RENEWABLE,

ref 2012-2050

TOTAL

24,500 BILLION USD

6,000

NUCLEAR, CHP, 8%

5,000

FOSSIL,

4,000 3,000

2,000

CHP,

e[r] 2012-2050

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

11%

RENEWABLE,

82%

USD

1,000

TOTAL

48,000 BILLION

11%

FOSSIL, 6% CHP, 8%

adv e[r] 2012-2050

TOTAL

64,600 BILLION

RENEWABLE,

86%

USD

world energy [r]evolution a sustainable world energy outlook

6.1.5 energy supply for heating table 6.1.2 | global: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in PJ /a

Today, renewables meet around 21% of World’s energy demand for heating, the main contribution coming from the use of biomass. Dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. In the basic Energy [R]evolution scenario, renewables already provide 42% of World’s total heat demand in 2030 and 86% in 2050.

REf E[R] ADv

SOLAR HEATING

REf E[R]

• Energy efficiency measures help to reduce the currently growing energy demand for heating by 33% in 2050 (relative to the Reference scenario), in spite of improving living standards and economic growth.

ADv GEOTHERMAL HEAT REf AND HEAT PuMPS

E[R] ADv

HyDROGEN

• In the industry sector solar collectors, geothermal energy (incl. heat pumps) as well as electricity and hydrogen from renewable sources are increasingly substituting for fossil fuel-fired systems.

REf E[R] ADv ref

total

e[r] adv

2012 27,486 27,486 27,486 804 804 804 484 484 484 0 0 0 28,773 28,773 28,773

2020 31,115 34,907 34,909 1,746 6,982 6,994 810 5,197 5,197 0 163 375 33,672 47,249 47,476

2030 32,467 36,619 36,623 2,107 12,984 12,994 929 10,417 10,417 0 366 986 35,503 60,385 61,020

2040 35,590 38,504 38,527 2,845 25,704 25,901 1,277 24,612 25,018 0 1,862 5,622 39,711 90,682 95,069

2050 38,986 38,562 39,386 3,841 31,378 32,446 1,720 34,765 36,828 0 6,021 8,576 44,547 110,725 117,237

• A shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of CO 2 emissions. Table 6.1.2 shows the development of different renewable technologies for heating worldwide over time. up to 2030 biomass remains the main contributor of the growing market share. After 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will further reduce the dependence on fossil fuels. The Advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.1.9 | global: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 250,000

200,000

155,000 PJ/a

bIOMASS

EFFICIENCY

100,000

HYDROGEN ELECTRIC HEATING GEOTHERMAL HEATING

& HEAT PUMPS

50,000

SOLAR HEATING BIOMASS FOSSIL

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.1.6 future investments in the heating sector

Also in the heating sector the Energy [R]evolution scenarios would require a major revision of current investment strategies in heating technologies. In particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. The use of biomass for heating purposes often traditional biomass today - will be substantially reduced in the Energy [R]evolution scenarios and replaced by more efficient and sustainable renewable heating technologies. Renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. Thus, it can only be roughly estimated that the Energy [R]evolution scenario in total requires around uS$ 16,300 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) - approximately uS$ 420 billion per year.

table 6.1.3 | global: installed capacities for renewable heat generation under the scenarios

bIOMASS

REf E[R] ADv

GEOTHERMAL

REf E[R] ADv

SOLAR HEATING

REf E[R] ADv

HEAT PuMPS

REf E[R] ADv

total*

ref e[r] adv

2012 12,255 12,255 12,255 2 2 2 235 235 235 84 84 84 12,575 12,575 12,575

2020 12,662 12,418 12,418 3 52 52 401 749 749 119 229 229 13,186 13,448 13,448

2030 12,636 11,218 11,217 6 328 328 604 3,418 3,421 160 958 958 13,406 15,922 15,924

2040 12,287 9,329 9,329 8 852 855 810 6,640 6,700 221 1,998 2,054 13,325 18,819 18,938

2050 11,821 7,276 7,507 9 1,178 1,232 1,088 7,931 8,190 299 2,758 2,879 13,218 19,143 19,807

The Advanced scenario assumes an even more ambitious expansion of renewable technologies resulting in an average investment of around uS$ 429 billion per year, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with hydrogen or other synthetic fuels. 6.1.7 future employment in the energy sector

the advanced energy [r]evolution scenario results in more energy sector jobs at every stage of the projection. • There are 36.2 million energy sector jobs in the Advanced Energy [R]evolution in 2020, and 30.1 million in the Reference scenario. • In 2025, there are 46.7 million jobs in the Advanced Energy [R]evolution scenario, and 29.6 million in the Reference scenario. • In 2030, there are 48 million jobs in the Advanced Energy [R]evolution scenario and 28 million in the Reference scenario. figure 6.1.11 shows the change in job numbers under all scenarios for each technology between 2015 and 2030. jobs in the coal sector decline in both the Reference scenario and the Advanced Energy [R]evolution scenario, as a result of productivity improvements in the industry, coupled with a move away from coal in the Advanced Energy [R]evolution scenario. In the Reference scenario jobs increase slightly to 2020, after which energy sector jobs decline. This is mainly driven by losses in the coal sector. At 2030, jobs are 3% (2.2 million) below 2015 levels. In the Advanced Energy [R]evolution scenario, strong growth in the renewable sector leads to an increase of 26% in total energy sector jobs by 2020, and job numbers are nearly 70% above 2015 levels in 2025. job numbers continue to rise after 2025, to reach 46.1 million by 2030. Renewable energy accounts for 86% of energy jobs by 2030. The greatest share are in biomass (25%), followed by solar Pv and wind energy.

* Excluding direct electric heating.

figure 6.1.10 | global: development of investments for renewable heat generation technologies – reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050

e[r] 2012-2050

BIOMASS,

67% HEAT PUMPS, 15% SOLAR,

adv e[r] 2012-2050

BIOMASS,

11%

GEOTHERMAL,

18%

15%

TOTAL

GEOTHERMAL,

10%

GEOTHERMAL,

16%

TOTAL

16,300 BILLION USD

4,100 BILLION USD

BIOMASS,

16,700 BILLION USD HEAT PUMPS, SOLAR,

38%

36%

HEAT PUMPS, SOLAR,

36%

38%

world energy [r]evolution a sustainable world energy outlook

figure 6.1.11 | global: employment in the energy sector under the reference and advanced energy [r]evolution scenario

figure 6.1.12 | global: global proportion of fossil fuel and renewable employment in 2015 and 2030

COAL,

50 45

2015 both sCenarios

51%

TOTAL

29 MILLION JOBS

Direct jobs - Millions

34%

RENEWABLE,

GAS, OIL

& DIESEL, 12% 3%

NUCLEAR,

COAL,

2030 referenCe sCenario

15 10

28%

RENEWABLE,

53%

TOTAL

28 MILLION JOBS

GAS, OIL

& DIESEL, 16% 3%

NUCLEAR,

2015

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

& HEAT PUMP

2025

2030

2030 adv energy [r]evolution

WIND

- HEAT

COAL, 4% GAS, OIL & DIESEL, NUCLEAR, 1%

ADV E[R] TOTAL

48 MILLION

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

RENEWABLE,

JOBS

HYDRO

OCEAN

86%

& DIESEL

table 6.1.4 | global: total employment in the energy sector

in Million Jobs

advanced e [ r ] scenario

reference scenario

2015

2020

2025

2030

2020

2025

2030

9.68 3.51 0.71 14.48 28.38

9.59 3.96 0.84 15.24 29.62

8.56 4.30 0.80 15.40 29.06

7.62 4.37 0.71 14.64 27.34

4.78 3.91 0.51 26.28 35.48

3.27 4.08 0.50 37.36 45.21

1.96 3.93 0.49 39.76 46.14

4.74 2.33 3.10 17.60 0.61 28.38

4.96 2.38 3.79 17.83 0.66 29.62

4.47 2.18 4.13 17.60 0.67 29.06

3.81 1.85 4.09 16.91 0.69 27.34

7.96 5.37 4.62 17.08 0.45 35.48

13.84 8.59 6.64 15.75 0.39 45.21

14.62 9.18 8.54 13.43 0.37 46.14

9.68 3.51 0.71 10.93 1.39 0.69 1.00 0.03 0.02 0.00 0.36 0.07 28.4

9.59 3.96 0.84 11.80 1.39 0.71 0.84 0.03 0.04 0.00 0.37 0.05 29.6

8.56 4.30 0.80 12.00 1.39 0.75 0.81 0.03 0.05 0.00 0.33 0.04 29.1

7.62 4.37 0.71 11.71 1.22 0.64 0.63 0.03 0.07 0.01 0.30 0.04 27.3

4.78 3.91 0.51 11.94 0.96 4.10 6.46 0.18 0.42 0.22 1.54 0.46 35.5

3.27 4.08 0.50 12.38 0.79 6.65 10.52 0.29 1.58 0.43 3.78 0.95 45.2

1.96 3.93 0.49 11.35 0.68 7.82 9.69 0.37 2.50 0.63 5.33 1.40 46.1

by fuel

COAL GAS, OIL

DIESEL

NuCLEAR RENEWAbLES total jobs by sector

CONSTRuCTION AND INSTALLATION MANufACTuRING OPERATIONS AND MAINTENANCE fuEL SuPPLy (DOMESTIC) COAL AND GAS ExPORT total jobs (million) by technology

COAL GAS, OIL

DIESEL

NuCLEAR bIOMASS HyDRO WIND Pv GEOTHERMAL POWER SOLAR THERMAL POWER OCEAN SOLAR

HEAT

GEOTHERMAL

HEAT PuMP

total jobs (million)

energy

[r]evolution

6.1.8 transport table 6.1.5 | global: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in PJ /a

A key target is to introduce incentives for people to drive smaller cars and buy new, more efficient vehicle concepts. In addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the expanding large metropolitan areas. Along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the Reference scenario. Due to population increase, GDP growth and higher living standards, energy demand from the transport sector is expected to increase in the Reference scenario by around 65% to 1480,00 Pj/a in 2050. In the basic Energy [R]evolution scenario, efficiency measures and modal shifts will save 53% (78,700 Pj/a) in 2050 compared to the Reference scenario.

RAIL

REf E[R] ADv

ROAD

REf E[R] ADv

DOMESTIC AvIATION REf E[R] ADv

Additional modal shifts and technology switches lead to even higher energy savings in the Advanced scenario of 62% (92,000 Pj/a) in 2050 compared to the Reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. by 2030, electricity will provide 9% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the Energy [R]evolution, while in 2050 the share will be 39% (14%/52% in the Advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. In 2050, up to 14,000 Pj/a of hydrogen is used in the transport sector for the Advanced Energy [R]evolution scenario. A global maximum of 9,300 Pj/a of biofuels is used in the basic Energy [R]evolution in 2050 while in the Advanced case consumption is lower (around 8,000 Pj/a).

DOMESTIC

REf

NAvIGATION

E[R] ADv ref

total

e[r] adv

2012 2,766 2,766 2,766 78,688 78,688 78,688 4,120 4,120 4,120 2,173 2,173 2,173 87,748 87,748 87,748

2020 3,335 3,110 3,278 98,701 83,781 82,720 5,512 4,683 4,636 2,707 2,492 2,492 110,256 94,065 93,125

2030 3,517 3,338 4,718 107,510 79,473 72,094 5,943 4,712 4,423 2,963 2,728 2,698 119,934 90,252 83,934

2040 3,887 3,631 6,774 120,944 67,361 53,463 6,730 4,667 3,885 3,269 2,849 2,739 134,829 78,509 66,862

2050 4,260 3,751 8,356 130,313 57,356 41,487 7,573 5,004 3,602 3,470 2,860 2,700 145,616 68,972 56,145

figure 6.1.13 | global: final energy consumption in transport under the scenarios

160,000 140,000 120,000

PJ/a

100,000 80,000 EFFICIENCY

60,000

HYDROGEN ELECTRICITY

40,000

SYNFUELS BIOFUELS

20,000

NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

world energy [r]evolution a sustainable world energy outlook

6.1.9 development of co 2 emissions

CO2 emissions [Mt/a]

Population (million)

50,000

10,000

45,000

9,000

40,000

8,000

35,000

7,000

30,000

6,000

25,000

5,000

20,000

4,000

15,000

3,000

10,000

2,000

5,000

1,000

6.1.10 primary energy consumption

Taking into account the assumptions discussed above, the resulting primary energy consumption under the Energy [R]evolution scenarios is shown in figure 6.1.14. under the basic Energy [R]evolution scenario, primary energy demand will decrease by 19% from today’s 534,870 Pj/a to around 433,000 Pj/a (excluding non-energy consumption). Compared to the Reference scenario, overall primary energy demand will be reduced by 50% in 2050 under the Energy [R]evolution scenario (Reference scenario: around 860,000 Pj in 2050). The Advanced scenario results due to additional conversion losses in a primary energy consumption of around 450,000 Pj in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

expansion of renewable energies and a fast introduction of very efficient vehicle concepts in the transport sector to replace oil based combustion engines. This leads to an overall renewable primary energy share of 33% in 2030 and 76% in 2050 in the basic Energy [R]evolution and of more than 92% in 2050 in the Advanced case (incl. non-energy consumption). In contrast to the Reference scenario, no new nuclear power plants will be built worldwide in the Energy [R]evolution scenarios.

The Energy [R]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by

figure 6.1.14 | global: projection of total primary energy demand (ped) by energy carrier including electricity iMPort balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 1,000,000 900,000 800,000 700,000

EFFICIENCY OCEAN ENERGY

600,000 PJ/a

figure 6.1.15 | global: development of co 2 emissions by sector under the energy [r]evolution scenarios ‘ savings ’ = reduction coMPared to the reference scenario

Whilst World’s emissions of CO 2 will increase by 56% between 2012 and 2050 under the Reference scenario, under the Energy [R]evolution scenario they will decrease from 30,470 million tonnes in 2012 to 4,360 million tonnes in 2050. Annual per capita emissions will drop from 4.3 tonne to 0.5 tonne. In spite of the abstinence of nuclear power production and increasing power demand, CO 2 emissions will decrease in the electricity sector. In the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well. With a 31% share of CO 2, the Industry sector will be the largest source of emissions in 2050 in the basic Energy [R]evolution scenario. by 2050, World´s CO 2 emissions are 80% below 1990 levels in the Energy [R]evolution scenario while energy consumption is fully decarbonised in the Advanced case.

GEOTHERMAL

500,000

SOLAR BIOMASS

400,000

WIND

300,000

HYDRO NATURAL GAS

200,000

CRUDE OIL

100,000

COAL NUCLEAR

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.1.6 | global: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

CONvENTIONAL (fOSSIL

bILLION,$

$ $

906.2 -1,530.0 -623.8

2,400.5 -8,308.7 -5,908.2

2,559.9 -10,579.9 -8,020.0

2,739.9 -11,945.4 -9,205.5

8,606.5 -32,363.9 -23,757.4

220.7 -829.8 -609.2

$ $ $ $ $ $

56.1 -125.0 216.7 32.5 63.4 243.7

475.7 1,408.6 2,281.2 253.7 384.2 4,803.4

753.4 5,585.4 5,590.2 442.3 698.5 13,069.8

618.7 10,882.4 7,964.9 562.0 945.4 20,973.3

1,904.0 17,751.4 16,053.0 1,290.5 2,091.4 39,090.4

48.8 455.2 411.6 33.1 53.6 1,002.3

DIffERENCE REf MINuS E[R]

RENEWAbLES

+ (INCL. CHP)

2012 - 2050 average per year

NuCLEAR)

bILLION bILLION

total accumulated fuel cost savings

SAvINGS CuMuLATIvE E[R] vERSuS REf

fuEL OIL

bILLION

GAS

bILLION

HARD COAL

bILLION

LIGNITE

bILLION

NuCLEAR ENERGy

bILLION

total

bILLION

table 6.1.7 | global: accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

RENEWAbLES

bILLION

DIffERENCE REf MINuS E[R]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

458.8

2,567.6

4,788.6

4,366.4

12,181.3

2012 - 2050 average per year

312.3

table 6.1.8 | global: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

CONvENTIONAL (fOSSIL

bILLION

DIffERENCE REf MINuS ADvANCED E[R]

RENEWAbLES

+ (INCL. CHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

987.3 -2,014.1 -1,026.9

2,448.9 -11,835.8 -9,386.9

2,441.1 -16,264.6 -13,823.5

2,528.7 -18,555.9 -16,027.1

8,406.0 -48,670.4 -40,264.5

215.5 -1,248.0 -1,032.4

$ $ $ $ $ $

51.5 -113.0 232.0 32.5 63.4 266.4

483.3 1,502.4 2,449.7 253.7 384.2 5,073.2

769.7 6,057.6 5,960.2 442.3 698.5 13,928.3

633.4 12,315.0 8,299.8 562.2 945.4 22,755.8

1,937.9 19,761.9 16,941.7 1,290.8 2,091.4 42,023.8

49.7 506.7 434.4 33.1 53.6 1,077.5

average per year

NuCLEAR)

bILLION bILLION

total accumulated fuel cost savings

SAvINGS CuMuLATIvE ADvANCED E[R] vERSuS REf

fuEL OIL

bILLION

GAS

bILLION

HARD COAL

bILLION

LIGNITE

bILLION

NuCLEAR ENERGy

bILLION

total

bILLION

table 6.1.9 | global: accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

RENEWAbLES

bILLION

DIffERENCE REf MINuS ADvANCED E[R]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

458.8

2,570.7

4,929.7

4,631.6

12,590.9

2012 - 2050 average per year

322.8

world energy [r]evolution a sustainable world energy outlook

6.2 oeCd north ameriCa This reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. The transformation to a carbon free energy system in the Advanced scenario will further increase the electricity demand in 2050 up to 5,000 TWh/a. Electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. Around 1,180 TWh are used in 2050 for electric vehicles and rail transport in 2050 in the Advanced scenario, around 900 TWh for hydrogen and 500 TWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.2.1 final energy demand by sector

Efficiency gains in the heating sector are large as well. under the Energy [R]evolution scenarios, consumption equivalent to about 7,400 Pj/a is avoided through efficiency gains by 2050 compared to the Reference scenario. As a result of energyrelated renovation of the existing stock of residential buildings, the introduction of low energy standards and ‘passive climatisation’ for new buildings, as well as highly efficient air conditioning systems, enjoyment of the same comfort and energy services will be accompanied with much lower future energy demand.

under both Energy [R]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.2.2). Total electricity demand will rise from about 4,460 TWh/a to 4,610 TWh/a by 2050 in the basic Energy [R]evolution scenario. Compared to the Reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 3,650 TWh/a.

figure 6.2.1 | oecd north america: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat froM chP autoProducers 90,000 80,000 70,000 60,000

PJ/a

Combining the projections on population development, GDP growth and energy intensity results in future development pathways for OECD North America’s final energy demand. These are shown in figure 6.2.1 for the Reference and Energy [R]evolution scenarios. under the Reference scenario, total final energy demand increases by 20% from the current 67,800 Pj/a to 81,600 Pj/a in 2050. In the basic Energy [R]evolution scenario, final energy demand decreases by 45% compared to current consumption and is expected to reach 37,300 Pj/a by 2050. The Advanced scenario results in some additional reductions due to a higher share of electric cars.

50,000 40,000 30,000 20,000

EFFICIENCY OTHER SECTORS

10,000

INDUSTRY TRANSPORT

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.2.4 | oecd north america: development of final energy demand for heat by sector in the energy [r]evolution scenarios

30,000

25,000

20,000

20,000 PJ/a

PJ/a

figure 6.2.2 | oecd north america: development of electricity demand by sector in the energy [r]evolution scenarios

15,000

10,000

5,000

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.2.3 | oecd north america: development of the final energy demand for transport by sector in the energy [r]evolution scenarios 35,000 30,000 25,000

PJ/a

20,000 15,000 10,000 5,000 0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

world energy [r]evolution a sustainable world energy outlook

6.2.2 electricity generation

HyDRO

REf E[R] ADv

bIOMASS

REf E[R] ADv

WIND

REf E[R] ADv

GEOTHERMAL

REf E[R] ADv

A 100% electricity supply from renewable energy resources in the Advanced scenario leads to around 3,100 GW installed generation capacity in 2050.

REf E[R] ADv

CSP

REf E[R]

Table 6.2.1 shows the comparative evolution of the different renewable technologies in OECD North America over time. up to 2020 wind and Pv will become the main contributors to the growing market share. After 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. The Energy [R]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 41% to 47% by 2030 and 57% to 59% by 2050. Therefore, smart grids, demand side management (DSM), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

ADv OCEAN

REf E[R] ADv

total

ref e[r] adv

2012 204 204 204 16 16 16 67 67 67 4 4 4 9 9 9 1 1 1 0 0 0 300 300 300

2020 208 213 213 24 21 21 109 206 248 6 8 9 40 145 197 5 5 7 0 5 6 391 604 702

2030 217 225 227 31 27 27 144 544 661 7 31 38 70 668 893 9 101 149 1 26 33 479 1,621 2,028

2040 214 230 239 37 33 33 175 730 852 8 56 95 99 850 1 038 11 181 248 2 96 122 547 2,175 2,626

2050 214 233 257 45 62 37 207 763 971 10 80 134 133 869 1,224 14 198 286 4 149 193 626 2,353 3,102

figure 6.2.5 | oecd north america: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 10,000 9,000

OCEAN ENERGY CSP

8,000

GEOTHERMAL

7,000

BIOMASS PV

6,000 TWh/a

table 6.2.1 | oecd north america: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios in gw

The development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. This trend will more than compensate for the phasing out of nuclear power production in the Energy [R]evolution scenarios, continuously reducing the number of fossil fuelfired power plants as well. by 2050, 95% of the electricity produced in OECD North America will come from renewable energy sources in the basic Energy [R]evolution scenario. ‘New’ renewables – mainly wind, Pv, CSP and geothermal energy – will contribute 80% to the total electricity generation. Already by 2020 the share of renewable electricity production will be 32% and 66% by 2030. The installed capacity of renewables will reach about 1,620 GW in 2030 and 2,350 GW by 2050.

WIND

5,000

HYDRO HYDROGEN

4,000

NUCLEAR

3,000

DIESEL OIL

2,000

GAS

1,000

LIGNITE COAL

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.2.3 future costs of electricity generation

6.2.4 future investments in the power sector

figure 6.2.6 shows that the introduction of renewable technologies under both Energy [R]evolution scenarios increases the future costs of electricity generation compared to the Reference scenario until 2040. This difference in full cost of generation will be less than 1.5 uS$ct/kWh in the basic Energy [R]evolution and about 2.1 uS$ct/kWh in the Advanced scenario, without taking into account integration costs for storage or other load-balancing measures. because of increasing prices for conventional fuels, electricity generation costs will become economically favourable after 2040 under the Energy [R]evolution scenario. by 2050, in the Energy [R]evolution the cost will be 0.5 uS$ct/kWh below and in the Advanced scenario 0.4 uS$ct/kWh above those in the Reference case.

Around uS$ 8,300 billion is required in investment for the Energy [R]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately uS$ 213 billion per year, uS$ 4,020 billion more than in the Reference scenario (uS$ 4,280 billion). Investments for the Advanced scenario sum up to uS$ 10,620 billion until 2050, on average uS$ 272 billion per year, including high investments for additional power plants for the production of synthetic fuels. under the Reference scenario, the levels of investment in conventional power plants add up to almost 57% while approximately 43% would be invested in renewable energies and cogeneration until 2050.

under the Reference scenario, on the other hand, growth in demand and increasing fossil fuel prices result in total electricity supply costs rising from todayâ&#x20AC;&#x2122;s uS$ 303 billion per year to more than uS$ 645 billion in 2050, compared to uS$ 583 billion in the basic and uS$ 808 billion in the Advanced Energy [R]evolution scenario. figure 6.2.6 shows that both Energy [R]evolution scenarios not only comply with OECD North Americaâ&#x20AC;&#x2122;s CO 2 reduction targets, but also help stabilise energy costs and relieve the economic pressure on society. Increasing energy efficiency and shifting energy supply to renewables lead to long term costs for electricity supply that are more than 10% lower in the basic Energy [R]evolution scenario than in the Reference scenario. The Advanced scenario with 100% renewable power in supply costs 25% higher than the Reference case, but a reduction of CO 2 intensity to zero.

figure 6.2.6 | oecd north america: development of total electricity supply costs & of specific electricity generation costs in the scenarios Billion $

under the Energy [R]evolution scenarios, however, OECD North America would shift almost 90%/91% of the entire investment towards renewables and cogeneration, respectively. by 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants. because renewable energy has no fuel costs, the fuel cost savings in the basic Energy [R]evolution scenario reach a total of uS$ 4,390 billion up to 2050, uS$ 113 billion per year. The total fuel cost savings therefore would cover 110% of the total additional investments compared to the Reference scenario. fuel cost savings in the Advanced scenario are even higher and add up to uS$ 4,680 billion, or uS$ 120 billion per year. Renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.2.7 | oecd north america: investment shares - reference versus energy [r]evolution scenarios

US$ct/kWh

1,000

FOSSIL,

44% 39%

RENEWABLE,

900

800

700

600

CHP, 4% NUCLEAR,

500

FOSSIL,

400

300

200

100

ref 2012-2050

TOTAL

4,280 BILLION USD

CHP,

e[r] 2012-2050

TOTAL

8,300 BILLION

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

RENEWABLE,

82%

USD

0 REF E[R] ADV E[R]

13%

10%

FOSSIL, 9% CHP, 5%

adv e[r] 2012-2050

TOTAL

10,600 BILLION

RENEWABLE,

86%

USD

world energy [r]evolution a sustainable world energy outlook

6.2.5 energy supply for heating

bIOMASS

REf E[R] ADv

SOLAR HEATING

REf E[R] ADv

• The efficiency measures help to reduce the currently growing energy demand for heating by 29 % in 2050 (relative to the Reference scenario), in spite of improving living standards and economic growth.

GEOTHERMAL HEAT REf AND HEAT PuMPS

E[R] ADv

HyDROGEN

REf E[R]

ADv ref

total

e[r] adv

2012 1,784 1,784 1,784 68 68 68 14 14 14 0 0 0 1,866 1,866 1,866

2020 2,174 2,316 2,316 199 1,459 1,472 14 963 963 0 156 229 2,387 4,894 4,980

2030 2,338 2,367 2,367 272 2,548 2,561 14 1,760 1,760 0 316 398 2,624 6,991 7,086

2040 2,905 2,405 2,405 474 4,620 4,675 15 4,070 4,070 0 770 1,095 3,394 11,866 12,245

2050 3,658 1,932 1,932 766 5,275 5,292 15 5,817 5,813 0 1,089 2,928 4,439 14,112 15,965

• A shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of CO 2 emissions. Table 6.2.2 shows the development of different renewable technologies for heating in OECD North America over time. up to 2030 biomass remains the main contributor of the growing market share. After 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will further reduce the dependence on fossil fuels. The Advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.2.8 | oecd north america: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 30,000

25,000

20,000

PJ/a

table 6.2.2 | oecd north america: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in PJ /a

Today, renewables meet around 11% of OECD North America’s energy demand for heating, the main contribution coming from the use of biomass. Dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. In the basic Energy [R]evolution scenario, renewables already provide 39% of OECD North America’s total heat demand in 2030 and 89% in 2050.

15,000 EFFICIENCY HYDROGEN

10,000

ELECTRIC HEATING GEOTHERMAL HEATING

& HEAT PUMPS

5,000

SOLAR HEATING BIOMASS FOSSIL

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.2.6 future investments in the heating sector

Also in the heating sector the Energy [R]evolution scenarios would require a major revision of current investment strategies in heating technologies. In particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. The use of biomass for heating purposes - often traditional biomass today - will be substantially reduced in the Energy [R]evolution scenarios and replaced by more efficient and sustainable renewable heating technologies. Renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. Thus, it can only be roughly estimated that the Energy [R]evolution scenario in total requires around uS$ 3,550 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) approximately uS$ 91 billion per year. The Advanced scenario assumes the same ambitious expansion of renewable technologies, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with hydrogen or other synthetic fuels.

table 6.2.3 | oecd north america: installed capacities for renewable heat generation under the scenarios in gw

bIOMASS

REf E[R] ADv

GEOTHERMAL

REf E[R] ADv

SOLAR HEATING

REf E[R] ADv

HEAT PuMPS

REf E[R] ADv

total*

ref e[r] adv

2012 293 293 293 0 0 0 20 20 20 2 2 2 315 315 315

2020 343 347 347 0 13 13 37 166 166 2 35 35 382 561 561

2030 396 307 307 0 67 67 80 715 719 2 186 186 479 1,275 1,279

2040 450 223 223 0 170 170 140 1,265 1,281 2 435 435 592 2,093 2,109

2050 511 97 97 0 235 235 226 1,417 1,422 2 626 626 740 2,375 2,380

* Excluding direct electric heating.

figure 6.2.9 | oecd north america: development of investments for renewable heat generation technologies â&#x20AC;&#x201C; reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050

e[r] 2012-2050

adv e[r] 2012-2050

BIOMASS, SOLAR,

37%

GEOTHERMAL,

BIOMASS,

14%

GEOTHERMAL, HEAT PUMPS,

TOTAL

3,560 BILLION USD

3,550 BILLION USD HEAT PUMPS, BIOMASS,

63%

37%

TOTAL

660 BILLION USD

14%

SOLAR,

45%

37%

SOLAR,

45%

world energy [r]evolution a sustainable world energy outlook

6.2.7 future employment in the energy sector

the advanced Energy [R]evolution scenario results in more energy sector jobs in the oECD North america at every stage of the projection.

figure 6.2.10 | oecd north america: employment in the energy sector under the reference and advanced energy [r]evolution scenario

• there are 2.6 million energy sector jobs in the advanced energy [r]evolution in 2020, and 0.9 million in the reference scenario.

• in 2030, there are 2.7 million jobs in the advanced energy [r]evolution scenario and 1 million in the reference scenario. figure 6.2.10 shows the change in job numbers in both scenarios for each technology between 2015 and 2030. Jobs in the reference scenario increase very slightly over the period.

3.0

Direct jobs - Millions

• in 2025, there are 3.2 million jobs in the advanced energy [r]evolution scenario, and 1 million in the reference scenario.

3.5

exceptionally strong growth in the renewable sector leads to a sharp increase of 194% in energy sector jobs in the advanced energy [r]evolution scenario by 2020. after 2020 jobs in solar pV drop, but at 2030 jobs are still 205% above 2015 levels. renewable energy accounts for 88% of energy jobs in 2030, with the majority in solar pV, followed by wind energy.

2.5 2.0 1.5 1.0 0.5 0

2015

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

2030

ADV E[R]

& HEAT PUMP

WIND

- HEAT

HYDRO

OCEAN

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

table 6.2.4 | oecd north america: total employment in the energy sector

2025

& DIESEL

in thousand jobs

advanced energy [r]evolution

reference

2015

2020

2025

2030

2020

2025

2030

135 229 79 442 884

175 229 80 463 947

170 233 77 510 990

171 237 75 517 1,000

83 252 96 2,164 2,596

56 230 99 2,841 3,226

29 199 107 2,374 2,709

108 73 332 360 10 884

120 78 352 388 10 947

123 77 366 413 10 990

106 68 379 437 10 1,000

1,029 802 418 343 3 2,596

1,336 935 637 316 2 3,226

963 659 797 290 0 2,709

jobs by fuel

coal gas, oil

diesel

nuclear renewables total jobs jobs by sector

construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs

100

energy

[r]evolution

6.2.8 transport table 6.2.5 | oecd north america: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in pj /a

a key target in oecd north america is to introduce incentives for people to drive smaller cars and buy new, more efficient vehicle concepts. in addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the large metropolitan areas. along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the reference scenario. due to population increase, gdP growth and higher living standards, energy demand from the transport sector is expected to slightly increase in the reference scenario by around 7% to 31,710 PJ/a in 2050. in the basic energy [r]evolution scenario, efficiency measures and modal shifts will save 65% (20,630 PJ/a) in 2050 compared to the reference scenario.

rail

ref e[r] adv

road

ref e[r] adv

domestic aviation ref e[r] adv

additional modal shifts and technology switches lead to even higher energy savings in the advanced scenario of 72% (22,700 PJ/a) in 2050 compared to the reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. By 2030, electricity will provide 11% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the energy [r]evolution, while in 2050 the share will be 35% (47% in the advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. in 2050, up to 2,500 PJ/a of hydrogen is used in the transport sector for the advanced energy [r]evolution scenario.

domestic

ref

navigation

e[r] adv ref

total

e[r] adv

2012 663 663 663 25,564 25,564 25,564 2,161 2,161 2,161 550 550 550 28,938 28,938 28,938

2020 723 676 743 26,090 22,925 22,554 2,307 2,047 2,026 589 566 566 29,708 26,214 25,890

2030 749 686 1,043 26,039 17,497 15,654 2,372 1,762 1,639 602 598 598 29,762 20,543 18,934

2040 804 710 1,401 26,275 11,049 8,727 2,529 1,582 1,249 630 637 637 30,237 13,978 12,014

2050 877 559 1,399 26,487 7,927 5,615 2,717 1,678 1,091 657 696 696 30,738 10,860 8,801

figure 6.2.11 | oecd north america: final energy consumption in transport under the scenarios

35,000

30,000

25,000

PJ/a

20,000

15,000

EFFICIENCY HYDROGEN

10,000

ELECTRICITY SYNFUELS BIOFUELS

5,000

NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

101

world energy [r]evolution a sustainable world energy outlook

6.2.10 development of co 2 emissions

CO2 emissions [Mt/a]

With a 40% share of co 2, the transport sector will be the largest source of emissions in 2050 in the basic energy [r]evolution scenario. By 2050, oecd north america’s co 2 emissions are around 90% below 1990 levels in the energy [r]evolution scenario while energy consumption is fully decarbonised in the advanced case.

Population (million)

7,000

700

6,000

600

5,000

500

4,000

400

3,000

300

2,000

200

1,000

100

6.2.11 primary energy consumption

taking into account the assumptions discussed above, the resulting primary energy consumption under the energy [r]evolution scenarios is shown in figure 6.2.12. Under the basic energy [r]evolution scenario, primary energy demand will decrease by 46% from today’s 107,520 PJ/a to around 58,000 PJ/a. compared to the reference scenario, overall primary energy demand will be reduced by 54% in 2050 under the energy [r]evolution scenario (reference scanario: around 126,000 PJ in 2050). the advanced energy [r]evolution scenario results due to additional conversion losses in a primary energy consumption of around 61,100 PJ in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

renewable energies and a fast introduction of very efficient vehicle concepts in the transport sector to replace oil based combustion engines. this leads to an overall renewable primary energy share of 34% in 2030 and 80% in 2050 in the basic energy [r]evolution and of more than 92% in 2050 in the advanced case (incl. non-energy consumption). in contrast to the reference scenario, no new nuclear power plants will be built in oecd north america in the energy [r]evolution scenarios.

the energy [r]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by expansion of

figure 6.2.12 | oecd north america: projection of total primary energy demand (ped) by energy carrier including electricity import balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 140,000

120,000 NET ELECTRICITY IMPORTS

100,000

EFFICIENCY OCEAN ENERGY

80,000

GEOTHERMAL

PJ/a

figure 6.2.13 | oecd north america: development of co2 emissions by sector under the energy [r]evolution scenarios ‘savings ’ = reduction compared to the reference scenario

Whilst oecd north america’s emissions of co 2 will increase by 6% between 2012 and 2050 under the reference scenario, under the energy [r]evolution scenario they will decrease from 5,950 million tonnes in 2012 to 397 million tonnes in 2050. annual per capita emissions will drop from 12.5 tonne to 0.7 tonne. in spite of the abstinence of nuclear power production and increasing power demand, co 2 emissions will decrease in the electricity sector. in the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well.

SOLAR

60,000

BIOMASS WIND

40,000

HYDRO NATURAL GAS CRUDE OIL

20,000

COAL NUCLEAR

102

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.2.6 | oecd north america: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

289.1 -467.8 -178.8

403.8 -2,003.6 -178.8

416.2 -1,667.9 -1,599.8

521.5 -1,522.8 -1,251.6

1,630.6 -5,662.0 -1,001.3

41.8 -145.2 -103.3

$ $ $ $ $ $

6.9 -31.5 95.3 20.7 24.1 115.4

25.0 31.4 309.9 134.9 103.8 605.0

40.6 492.0 471.0 209.7 175.6 1,388.8

24.5 1,289.3 520.2 233.4 215.8 2,283.2

97.0 1,781.2 1,396.4 598.6 519.3 4,392.4

2.5 45.7 35.8 15.3 13.3 112.6

average per year nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.2.7 | oecd north america: accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

224.4

615.4

1,144.3

903.9

2,888.0

2012 - 2050 average per year

74.1

table 6.2.8 | oecd north america: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs advanced e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

337.3 -663.8 -326.5

402.6 -2,715.7 -2,313.1

329.7 -2,170.2 -1,840.5

471.4 -2,340.4 -1,869.0

1,541.1 -7,890.1 -6,349.0

39.5 -202.3 -162.8

$ $ $ $ $ $

6.9 -31.5 109.5 20.7 24.1 129.6

25.0 39.9 363.2 134.9 103.8 666.8

40.6 552.5 501.5 209.7 175.6 1,479.8

25.9 1,401.2 523.1 233.4 215.8 2,399.4

98.4 1,962.1 1,497.3 598.6 519.3 4,675.6

2.5 50.3 38.4 15.3 13.3 119.9

average per year

nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative advanced e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.2.9 | oecd north america: accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs advanced e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

224.4

619.1

1,155.3

902.7

2,901.4

2012 - 2050 average per year

74.4

103

world energy [r]evolution a sustainable world energy outlook

6.3 latin america this reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. the transformation to a carbon free energy system in the advanced scenario will further increase the electricity demand in 2050 up to 2,500 tWh/a. electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. around 600 tWh are used in 2050 for electric vehicles and rail transport in 2050 in the advanced scenario, around 430 tWh for hydrogen and 90 tWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.3.1 final energy demand by sector

efficiency gains in the heating sector are even larger than in the electricity sector. Under the energy [r]evolution scenarios, consumption equivalent to about 6,900 PJ/a is avoided through efficiency gains by 2050 compared to the reference scenario. as a result of energy-related renovation of the existing stock of residential buildings, the introduction of low energy standards and ‘passive climatisation’ for new buildings, as well as highly efficient air conditioning systems, enjoyment of the same comfort and energy services will be accompanied by much lower future energy demand.

Under both energy [r]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.3.2). total electricity demand will rise from about 990 tWh/a to 2,230 tWh/a by 2050 in the basic energy [r]evolution scenario. compared to the reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 840 tWh/a.

figure 6.3.1 | latin america: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat from chp autoproducers 40,000 35,000 30,000 25,000 PJ/a

combining the projections on population development, gdP growth and energy intensity results in future development pathways for latin america’s final energy demand. these are shown in figure 6.3.1 for the reference and energy [r]evolution scenarios. Under the reference scenario, total final energy demand increases by 91% from the current 19,000 PJ/a to 36,300 PJ/a in 2050. in the basic energy [r]evolution scenario, final energy demand decreases by 6% compared to current consumption and is expected to reach 17,900 PJ/a by 2050. the advanced scenario results in some additional reductions due to a higher share of electric cars.

20,000 15,000 10,000

EFFICIENCY OTHER SECTORS

5,000

INDUSTRY TRANSPORT

104

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.3.4 | latin america: development of final energy demand for heat by sector in the energy [r]evolution scenarios

figure 6.3.2 | latin america: development of electricity demand by sector in the energy [r]evolution scenarios 10,000

18,000

9,000

16,000

8,000

14,000

7,000

12,000 PJ/a

6,000 PJ/a

5,000 4,000

10,000 8,000 6,000

3,000

4,000

2,000

1,000

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.3.3 | latin america: development of the final energy demand for transport by sector in the energy [r]evolution scenarios 12,000

10,000

PJ/a

8,000

6,000

4,000

2,000

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

105

world energy [r]evolution a sustainable world energy outlook

6.3.2 electricity generation

Hydro

ref e[r] adv

Biomass

ref e[r] adv

Wind

ref e[r] adv

geotHermal

ref e[r] adv

a 100% electricity supply from renewable energy resources in the advanced scenario leads to around 1,230 gW installed generation capacity in 2050.

ref e[r] adv

csP

table 6.3.1 shows the comparative evolution of the different renewable technologies in latin america over time. Until 2040 hydro will remain the main renewable power source. By 2020 wind and Pv overtake biomass, currently the second largest contributor to the growing renewable market. after 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. the energy [r]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 25% to 33% by 2030 and 41% to 49% by 2050. therefore, smart grids, demand side management (dsm), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

ref e[r] adv

ocean

ref e[r] adv

total

ref e[r] adv

2012 148 148 148 14 14 14 4 4 4 1 1 1 0 0 0 0 0 0 0 0 0 166 166 166

2020 192 164 164 18 23 23 16 34 41 1 2 2 4 35 51 0 1 6 0 0 0 231 259 286

2030 242 166 167 22 42 45 31 92 128 2 4 4 11 111 170 1 23 45 0 1 10 309 438 569

2040 285 168 168 26 71 73 40 162 260 3 10 15 17 227 323 3 63 93 0 6 17 374 706 950

figure 6.3.5 | latin america: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 4,500 4,000

OCEAN ENERGY CSP

3,500

GEOTHERMAL BIOMASS

3,000

TWh/a

table 6.3.1 | latin america: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios in gw

the development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. this trend will more than compensate for the phasing out of nuclear power production in the energy [r]evolution scenarios, continuously reducing the number of fossil fuelfired power plants as well. By 2050, 94% of the electricity produced in latin america will come from renewable energy sources in the basic energy [r]evolution scenario. ‘new’ renewables – mainly wind, Pv, csP and geothermal energy – will contribute 50% to the total electricity generation. already by 2020 the share of renewable electricity production will be 71% and 84% by 2030. the installed capacity of renewables will reach about 440 gW in 2030 and 930 gW by 2050.

2,500

WIND HYDRO

2,000

HYDROGEN NUCLEAR

1,500

DIESEL

1,000

OIL GAS

500

LIGNITE COAL

106

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2050 304 169 169 29 102 105 51 225 344 4 18 32 26 322 461 5 80 94 0 10 25 418 926 1,230

energy

[r]evolution

6.3.3 future costs of electricity generation

6.3.4 future investments in the power sector

figure 6.3.6 shows that the introduction of renewable technologies under both energy [r]evolution scenarios increases the future costs of electricity generation compared to the reference scenario before 2030. this difference in full cost of generation will be less than 0.2 Us$ct/kWh in the basic energy [r]evolution scenario and slightly more than 0.2 Us$ct/kWh in the advanced scenario, without taking into account integration costs for storage or other load-balancing measures. Because of increasing prices for conventional fuels, electricity generation costs will become economically favourable starting in 2030 under the energy [r]evolution scenarios. By 2050, the cost will be 1.8 Us$ct/kWh below those in the reference case.

around Us$ 2,600 billion is required in investment for the energy [r]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 67 billion per year, Us$ 1,200 billion more than in the reference scenario (Us$ 1,400 billion). investments for the advanced scenario sum up to Us$ 3,390 billion until 2050, on average Us$ 87 billion per year. Under the reference scenario, the levels of investment in conventional power plants add up to almost 24% while approximately 76% would be invested in renewable energies and cogeneration until 2050.

Under the reference scenario, on the other hand, growth in demand and increasing fossil fuel prices result in total electricity supply costs rising from todayâ&#x20AC;&#x2122;s Us$ 87 billion per year to more than Us$ 279 billion in 2050, compared to Us$ 270 billion in the basic and Us$ 331 billion in the advanced energy [r]evolution scenario. figure 6.3.6 shows that both energy [r]evolution scenarios not only comply with latin americaÂ´s co 2 reduction targets, but also help stabilise energy costs and relieve the economic pressure on society. increasing energy efficiency and shifting energy supply to renewables lead to long term costs for electricity supply that are 3% lower in the basic energy [r]evolution scenario than in the reference scenario despite a 7% increase in electricity production. the advanced scenario with 100% renewable power and an increase in power generation of 36% results in supply costs 19% higher than the reference case.

figure 6.3.6 | latin america: development of total electricity supply costs & of specific electricity generation costs in the scenarios Billion $

Under the energy [r]evolution scenarios, however, latin america would shift almost 94%/97% of the entire investment towards renewables and cogeneration, respectively. By 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants. Because renewable energy has no fuel costs, the fuel cost savings in the basic energy [r]evolution scenario reach a total of Us$ 1,880 billion up to 2050, Us$ 48 billion per year. the total fuel cost savings therefore would cover 160% of the total additional investments compared to the reference scenario. fuel cost savings in the advanced scenario are even higher and add up to Us$ 2,040 billion, or Us$ 52 billion per year. renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.3.7 | latin america: investment shares reference versus energy [r]evolution scenarios

US$ct/kWh

FOSSIL,

22%

500

450

400

350

300

RENEWABLE,

250

FOSSIL,

200

150

100

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

ref 2012-2050

TOTAL

1,400 BILLION USD

NUCLEAR, CHP,

CHP,

e[r] 2012-2050

71%

6% 12%

TOTAL

2,600 BILLION USD

RENEWABLE,

82%

FOSSIL, 3% CHP, 8%

adv e[r] 2012-2050

TOTAL

3,390 BILLION USD

RENEWABLE,

89% 107

world energy [r]evolution a sustainable world energy outlook

6.3.5 energy supply for heating table 6.3.2 | latin america: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in pj /a

today, renewables meet around 39% of latin america’s energy demand for heating, the main contribution coming from the use of biomass. dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. in the basic energy [r]evolution scenario, renewables already provide 63% of latin america’s total heat demand in 2030 and 93% in 2050.

ref e[r] adv

solar Heating

ref e[r]

• energy efficiency measures help to reduce the currently growing energy demand for heating by 43 % in 2050 (relative to the reference scenario), in spite of improving living standards and economic growth.

adv geotHermal Heat ref and Heat PUmPs

e[r] adv

Hydrogen

• in the industry sector solar collectors, geothermal energy (incl. heat pumps) as well as electricity and hydrogen from renewable sources are increasingly substituting for fossil fuel-fired systems.

ref e[r] adv ref

total

e[r] adv

2012 2,314 2,314 2,314 22 22 22 0 0 0 0 0 0 2,336 2,336 2,336

2020 2,726 3,076 3,079 74 515 515 0 177 178 0 1 1 2,800 3,769 3,773

2030 2,950 3,359 3,365 94 828 828 0 296 296 0 13 7 3,044 4,497 4,496

2040 3,616 3,557 3,479 149 1,380 1,380 0 859 872 0 58 230 3,765 5,854 5,961

2050 4,213 3,734 3,608 220 1,395 1,395 0 1,474 1,487 0 359 1,045 4,433 6,963 7,533

• a shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of co 2 emissions. table 6.3.2 shows the development of different renewable technologies for heating in latin america over time. although biomass remains the main contributor, its market share is decrasing and with it unefficient traditional biomass. after 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will further reduce the dependence on fossil fuels. the advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.3.8 | latin america: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 18,000 16,000 14,000 12,000

PJ/a

Biomass

10,000 8,000

EFFICIENCY

6,000

ELECTRIC HEATING

4,000

& HEAT PUMPS

HYDROGEN

GEOTHERMAL HEATING

SOLAR HEATING

2,000

BIOMASS FOSSIL

108

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.3.6 future investments in the heating sector

also in the heating sector the energy [r]evolution scenarios would require a major revision of current investment strategies in heating technologies. in particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. the use of biomass for heating purposes - often traditional biomass today - will be substantially reduced in the energy [r]evolution scenarios and replaced by more efficient and sustainable renewable heating technologies. renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. thus, it can only be roughly estimated that the energy [r]evolution scenario in total requires around Us$ 580 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 15 billion per year. the advanced scenario assumes an equally ambitious expansion of renewable technologies resulting in an average investment of around Us$ 15 billion per year, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with electricity, hydrogen or other synthetic fuels.

table 6.3.3 | latin america: installed capacities for renewable heat generation under the scenarios in gw

Biomass

ref e[r] adv

geotHermal

ref e[r] adv

solar Heating

ref e[r] adv

Heat PUmPs

ref e[r] adv

total*

ref e[r] adv

2012 610 610 610 0 0 0 5 5 5 0 0 0 616 616 616

2020 626 720 720 0 1 1 13 75 75 0 10 10 640 805 805

2030 694 741 741 0 6 6 23 205 205 0 21 21 718 972 972

2040 761 600 572 0 17 17 37 340 340 0 43 43 798 1,000 973

2050 779 462 416 0 22 22 55 342 342 0 65 65 833 892 845

* excluding direct electric heating.

figure 6.3.9 | latin america: development of investments for renewable heat generation technologies â&#x20AC;&#x201C; reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050 SOLAR,

e[r] 2012-2050

adv e[r] 2012-2050

BIOMASS,

31%

HEAT PUMPS, TOTAL

24%

TOTAL

255 BILLION USD

93%

31%

HEAT PUMPS,

24%

GEOTHERMAL,

TOTAL

580 BILLION USD

BIOMASS,

580 BILLION USD GEOTHERMAL, SOLAR,

36%

SOLAR,

36%

109

world energy [r]evolution a sustainable world energy outlook

6.3.7 future employment in the energy sector

the advanced Energy [R]evolution scenario results in more energy sector jobs in latin america at every stage of the projection.

figure 6.3.10 | latin america: employment in the energy sector under the reference and advanced energy [r]evolution scenario

• there are 2.5 million energy sector jobs in the advanced energy [r]evolution in 2020, and 1.7 million in the reference scenario.

• in 2030, there are 3.3 million jobs in the advanced energy [r]evolution scenario and 1.7 million in the reference scenario. figure 6.3.10 shows the change in job numbers under both scenarios for each technology between 2015 and 2030. Jobs in the reference scenario increase by 19% by 2030. biomass has the largest share in this scenario, followed by gas and then hydro.

3.0

Direct jobs - Millions

• in 2025, there are 2.8 million jobs in the advanced energy [r]evolution scenario, and 1.7 million in the reference scenario.

3.5

2.5 2.0 1.5 1.0 0.5 0

exceptionally strong growth in renewable energy leads to an increase of 68% in energy sector jobs in the advanced energy [r]evolution scenario by 2020, offsetting loses in the fossil fuel sectors. Jobs continue to rise to 129% above 2015 levels by 2030. renewable energy accounts for 91% of energy sector jobs in 2030, with biomass having the largest share (30%), followed by solar pV and wind.

2015

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

& HEAT PUMP

- HEAT

2030

ADV E[R] WIND HYDRO

OCEAN

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

table 6.3.4 | latin america: total employment in the energy sector

2025

& DIESEL

in thousand jobs

advanced energy [r]evolution

reference

2015

2020

2025

2030

2020

2025

2030

86 395 9 935 1,425

80 443 9 1,001 1,534

88 475 10 1,075 1,648

107 477 11 1,100 1,695

34 385 4 1,971 2,393

26 334 5 2,386 2,752

13 284 6 2,965 3,268

232 100 274 771 47 1,425

219 97 308 868 41 1,534

214 98 340 956 41 1,648

187 90 361 1,017 41 1,695

759 328 416 872 19 2,393

871 422 547 903 10 2,752

1,012 624 685 947 1 3,268

jobs by fuel

coal gas, oil

diesel

nuclear renewables total jobs jobs by sector

construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs

110

energy

[r]evolution

6.3.8 transport table 6.3.5 | latin america: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in pj /a

a key target in latin america is to introduce incentives for people to drive smaller cars and buy new, more efficient vehicle concepts. in addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the expanding large metropolitan areas. along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the reference scenario. due to population increase, gdP growth and higher living standards, energy demand from the transport sector is expected to increase in the reference scenario by around 61% to 11,030 PJ/a in 2050. in the basic energy [r]evolution scenario, efficiency measures and modal shifts will save 47% (5,150 PJ/a) in 2050 compared to the reference scenario.

rail

ref e[r] adv

road

ref e[r] adv

domestic aviation ref e[r] adv

additional modal shifts and technology switches lead to even higher energy savings in the advanced scenario of 57% (6,290 PJ/a) in 2050 compared to the reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. By 2030, electricity will provide 6% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the energy [r]evolution, while in 2050 the share will be 31% (46% in the advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. in 2050, up to 1,180 PJ/a of hydrogen is used in the transport sector for the advanced energy [r]evolution scenario.

domestic

ref

navigation

e[r] adv ref

total

e[r] adv

2012 93 93 93 5,216 5,216 5,216 164 164 164 108 108 108 5,580 5,580 5,580

2020 196 143 163 8,286 7,326 7,052 288 229 219 168 164 164 8,938 7,862 7,599

2030 225 146 257 9,093 6,836 5,941 324 241 225 186 205 205 9,828 7,428 6,627

2040 284 173 415 10,099 5,886 4,489 386 278 245 223 258 258 10,991 6,594 5,407

2050 343 170 442 9,856 5,053 3,742 418 301 253 259 307 307 10,876 5,831 4,744

figure 6.3.11 | latin america: final energy consumption in transport under the scenarios

12,000

10,000

PJ/a

8,000

6,000 EFFICIENCY HYDROGEN

4,000

ELECTRICITY SYNFUELS

2,000

BIOFUELS NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

111

world energy [r]evolution a sustainable world energy outlook

6.3.10 development of co 2 emissions

CO2 emissions [Mt/a]

population (million) 700

2,500

600

2,000

500 1,500

With a 39% share of co 2, the transport sector will be the largest source of emissions in 2050 in the basic energy [r]evolution scenario. By 2050, latin america’s co 2 emissions are around 76% below 1990 levels in the energy [r]evolution scenario while energy consumption is fully decarbonised in the advanced case.

400 300

1,000

200 500

100

6.3.11 primary energy consumption

taking into account the assumptions discussed above, the resulting primary energy consumption under the energy [r]evolution scenarios is shown in figure 6.3.12. Under the basic energy [r]evolution scenario, primary energy demand increases slightly from today’s 27,120 PJ/a and starts to decrease after 2020 to again around 27,000 PJ/a in 2050. compared to the reference scenario, overall primary energy demand will be reduced by 44% in 2050 under the energy [r]evolution] scenario (reference scenario: around 49,000 PJ in 2050). the advanced scenario results due to additional conversion losses in a primary energy consumption of around 28,700 PJ in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

expansion of renewable energies and a fast introduction of very efficient vehicle concepts in the transport sector to replace oil based combustion engines. this leads to an overall renewable primary energy share of 52% in 2030 and 86% in 2050 in the basic energy [r]evolution and of more than 95% in 2050 in the advanced case (incl. non-energy consumption). in contrast to the reference scenario, no new nuclear power plants will be built in latin america in the energy [r]evolution scenarios.

the energy [r]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by

figure 6.3.12 | latin america: projection of total primary energy demand (ped) by energy carrier including electricity including electricity import balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 60,000

50,000 NET ELECTRICITY IMPORTS

40,000

EFFICIENCY OCEAN ENERGY

PJ/a

figure 6.3.13 | latin america: development of co2 emissions by sector under the energy [r]evolution scenarios ‘savings ’ = reduction compared to the reference scenario

Whilst latin america’s emissions of co 2 will increase by 78% between 2012 and 2050 under the reference scenario, under the energy [r]evolution scenario they will decrease from 1,230 million tonnes in 2012 to 138 million tonnes in 2050. annual per capita emissions will drop from 2.5 tonne to 0.2 tonne. in spite of the abstinence of nuclear power production and increasing power demand, co 2 emissions will decrease in the electricity sector. in the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well.

GEOTHERMAL

30,000

SOLAR BIOMASS

20,000

WIND HYDRO NATURAL GAS

10,000

CRUDE OIL COAL NUCLEAR

112

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.3.6 | latin america: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

17.9 -44.2 -26.3

40.5 -251.6 -211.2

54.4 -556.3 -501.9

80.2 -548.3 -468.1

193.0 -1,400.5 -1,207.6

4.9 -35.9 -31.0

$ $ $ $ $ $

7.5 4.8 7.2 0.1 0.7 20.3

56.3 168.2 25.9 0.8 5.2 256.5

88.9 474.1 49.0 1.8 10.2 624.0

58.9 810.1 88.1 2.3 15.0 974.4

211.7 1,457.2 170.2 5.0 31.1 1,875.2

5.4 37.4 4.4 0.1 0.8 48.1

average per year nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.3.7 | latin america: accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

73.8

83.6

122.8

45.1

325.4

2012 - 2050 average per year

8.3

table 6.3.8 | latin america: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs advanced e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

21.5 -120.1 -98.6

50.0 -536.1 -486.1

59.0 -841.5 -782.5

113.0 -743.3 -630.3

243.4 -2,240.9 -1,997.5

6.2 -57.5 -51.2

$ $ $ $ $ $

2.9 18.3 7.6 0.1 0.7 29.5

53.2 214.4 29.5 0.8 5.2 303.0

86.3 526.5 51.7 1.8 10.2 676.5

58.6 868.4 88.3 2.3 15.0 1,032.6

200.9 1,627.7 177.0 5.0 31.1 2,041.7

5.2 41.7 4.5 0.1 0.8 52.4

average per year

nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative advanced e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.3.9 | latin america: accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs advanced e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

73.8

83.6

122.8

44.9

325.2

2012 - 2050 average per year

8.3

113

world energy [r]evolution a sustainable world energy outlook

6.4 oecd europe this reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. the transformation to a carbon free energy system in the advanced scenario will further increase the electricity demand in 2050 up to 3,900 tWh/a. electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. around 710 tWh are used in 2050 for electric vehicles and rail transport in 2050 in the advanced scenario, around 580 tWh for hydrogen and 210 tWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.4.1 final energy demand by sector

efficiency gains in the heating sector are even larger than in the electricity sector. Under the energy [r]evolution scenarios, consumption equivalent to about 8,800 PJ/a is avoided through efficiency gains by 2050 compared to the reference scenario. as a result of energy-related renovation of the existing stock of residential buildings, the introduction of low energy standards and ‘passive climatisation’ for new buildings, as well as highly efficient air conditioning systems, enjoyment of the same comfort and energy services will be accompanied with much lower future energy demand.

Under both energy [r]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.4.2). total electricity demand will rise from about 3,070 tWh/a to 3,420 tWh/a by 2050 in the basic energy [r]evolution scenario. compared to the reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 1,700 tWh/a.

figure 6.4.1 | oecd europe: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat from chp autoproducers 60,000

50,000

40,000

PJ/a

combining the projections on population development, gdP growth and energy intensity results in future development pathways for oecd europe’s final energy demand. these are shown in figure 6.4.1 for the reference and energy [r]evolution scenarios. Under the reference scenario, total final energy demand increases by 15% from the current 46,600 PJ/a to 53,500 PJ/a in 2050. in the basic energy [r]evolution scenario, final energy demand decreases by 36% compared to current consumption and is expected to reach 29,800 PJ/a by 2050. the advanced scenario results in some additional reductions due to a higher share of electric cars.

30,000

20,000 EFFICIENCY

10,000

OTHER SECTORS INDUSTRY TRANSPORT

114

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.4.4 | oecd europe: development of final energy demand for heat by sector in the energy [r]evolution scenarios

figure 6.4.2 | oecd europe: development of electricity demand by sector in the energy [r]evolution scenarios

30,000

18,000 16,000

25,000

14,000 20,000

10,000

PJ/a

12,000

8,000

15,000

10,000

6,000 4,000

5,000

2,000 0

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.4.3 | oecd europe: development of the final energy demand for transport by sector in the energy [r]evolution scenarios 16,000 14,000 12,000

PJ/a

10,000 8,000 6,000 4,000 2,000 0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

115

world energy [r]evolution a sustainable world energy outlook

6.4.2 electricity generation

Hydro

ref e[r] adv

Biomass

ref e[r] adv

Wind

ref e[r] adv

geotHermal

ref e[r] adv

a 100% electricity supply from renewable energy resources in the advanced scenario leads to around 2,280 gW installed generation capacity in 2050.

ref e[r] adv

csP

table 6.4.1 shows the comparative evolution of the different renewable technologies in oecd europe over time. Up to 2020 wind and Pv will become the main contributors to the growing market share. after 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. the energy [r]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 35% to 38% by 2030 and 56% to 62% by 2050. therefore, smart grids, demand side management (dsm), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

ref e[r] adv

ocean

ref e[r] adv

total

ref e[r] adv

2012 202 202 202 33 33 33 102 102 102 2 2 2 68 68 68 2 2 2 0 0 0 409 409 409

2020 214 214 214 44 57 61 176 207 210 2 2 2 113 168 173 3 4 4 0 1 1 553 653 664

2030 225 216 216 49 95 100 235 363 416 3 10 14 132 341 425 5 16 30 2 12 14 651 1,053 1,216

2040 232 219 219 53 97 105 273 502 672 3 24 34 145 513 675 9 43 66 11 34 42 727 1,432 1,813

figure 6.4.5 | oecd europe: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 7,000 OCEAN ENERGY

6,000

CSP GEOTHERMAL

5,000

TWh/a

table 6.4.1 | oecd europe: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios in gw

the development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. this trend will more than compensate for the phasing out of nuclear power production in the energy [r]evolution scenarios, continuously reducing the number of fossil fuelfired power plants as well. By 2050, 94% of the electricity produced in oecd europe will come from renewable energy sources in the basic energy [r]evolution scenario. ‘new’ renewables – mainly wind, Pv, csP and geothermal energy – will contribute 64% to the total electricity generation. already by 2020 the share of renewable electricity production will be 42% and 66% by 2030. the installed capacity of renewables will reach about 1,050 gW in 2030 and 1,660 gW by 2050.

BIOMASS PV

4,000

WIND HYDRO

3,000

HYDROGEN NUCLEAR

2,000

DIESEL OIL GAS

1,000

LIGNITE COAL

116

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2050 240 223 223 59 100 108 310 570 831 4 41 52 156 620 926 14 65 85 19 45 53 803 1,664 2,279

energy

[r]evolution

6.4.3 future costs of electricity generation

6.4.4 future investments in the power sector

figure 6.4.6 shows that the introduction of renewable technologies under both energy [r]evolution scenarios increases the future costs of electricity generation compared to the reference scenario until 2030. this difference in full cost of generation will be less than 0.8 Us$ct/kWh in the basic energy [r]evolution and about 1 Us$ct/kWh in the advanced scenario, without taking into account integration costs for storage or other load-balancing measures. Because of increasing prices for conventional fuels, electricity generation costs will become economically favourable starting in 2040 under the energy [r]evolution scenario. By 2050, the cost will be 1.1 Us$ct/kWh below and in the advanced scenario equal to those in the reference case.

around Us$ 5,430 billion is required in investment for the energy [r]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 139 billion per year, Us$ 1,730 billion more than in the reference scenario (Us$ 3,700 billion). investments for the advanced scenario add up to Us$ 6,720 billion until 2050, on average Us$ 172 billion per year, including high investments in additional power plants for the production of synthetic fuels. Under the reference scenario, the levels of investment in conventional power plants add up to almost 30% while approximately 70% would be invested in renewable energies and cogeneration until 2050.

Under the reference scenario, on the other hand, growth in demand and increasing fossil fuel prices result in total electricity supply costs rising from todayâ&#x20AC;&#x2122;s Us$ 290 billion per year to more than Us$ 538 billion in 2050, compared to Us$ 427 billion in the basic and Us$ 601 billion in the advanced energy [r]evolution scenario. figure 6.4.6 shows that the energy [r]evolution scenario not only complys with oecd europeÂ´s co 2 reduction targets, but also helps stabilise energy costs and relieve the economic pressure on society. increasing energy efficiency and shifting energy supply to renewables lead to long term costs for electricity supply that are more than 21% lower in the basic energy [r]evolution scenario than in the reference scenario. the advanced scenario with 100% renewable power and an increase in power generation of 12% results in supply costs 12% higher than the reference case.

figure 6.4.6 | oecd europe: development of total electricity supply costs & of specific electricity generation costs in the scenarios Billion $

Under the energy [r]evolution scenarios, however, oecd europe would shift almost 93%/94% of the entire investment towards renewables and cogeneration, respectively. By 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants. Because renewable energy has no fuel costs, the fuel cost savings in the basic energy [r]evolution scenario reach a total of Us$ 3,610 billion up to 2050, Us$ 93 billion per year. the total fuel cost savings therefore would cover 210% of the total additional investments compared to the reference scenario. fuel cost savings in the advanced scenario are even higher and add up to Us$ 3,780 billion, or Us$ 97 billion per year. renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.4.7 | oecd europe: investment shares reference versus energy [r]evolution scenarios

US$ct/kWh

700

FOSSIL,

600

ref 2012-2050

TOTAL

3,700 BILLION USD

500

CHP,

FOSSIL, CHP,

300 4

e[r] 2012-2050

TOTAL

5,430 BILLION

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

12% 7%

16%

RENEWABLE,

77%

USD

100

NUCLEAR,

400

200

22% 58%

RENEWABLE,

FOSSIL, CHP,

adv e[r] 2012-2050

TOTAL

6,720 BILLION

13%

RENEWABLE,

81%

USD

117

world energy [r]evolution a sustainable world energy outlook

6.4.5 energy supply for heating table 6.4.2 | oecd europe: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in pj /a

today, renewables meet around 16% of oecd europe’s energy demand for heating, the main contribution coming from the use of biomass. dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. in the basic energy [r]evolution scenario, renewables already provide 45% of oecd europe’s total heat demand in 2030 and 86% in 2050.

ref e[r] adv

solar Heating

ref e[r]

• energy efficiency measures help to reduce the currently growing energy demand for heating by 33% in 2050 (relative to the reference scenario), in spite of improving living standards and economic growth.

adv geotHermal Heat ref and Heat PUmPs

e[r] adv

Hydrogen

ref e[r] adv ref

total

e[r] adv

2012 2,387 2,387 2,387 107 107 107 179 179 179 0 0 0 2,673 2,673 2,673

2020 3,167 3,448 3,448 281 1,149 1,149 301 1,030 1,030 0 0 48 3,749 5,627 5,675

2030 3,441 3,712 3,712 351 1,816 1,816 344 1,870 1,870 0 3 174 4,135 7,401 7,572

2040 4,007 3,770 3,770 500 3,061 3,209 467 4,018 4,108 0 132 756 4,974 10,981 11,842

2050 4,717 3,874 3,940 685 3,811 4,016 620 5,080 5,301 0 627 2,283 6,022 13,393 15,540

• a shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of co 2 emissions. table 6.4.2 shows the development of different renewable technologies for heating in oecd europe over time. Up to 2030 biomass remains the main contributor of the growing market share. after 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will further reduce the dependence on fossil fuels. the advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.4.8 | oecd europe: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 30,000

25,000

20,000

PJ/a

Biomass

15,000 EFFICIENCY HYDROGEN

10,000

ELECTRIC HEATING GEOTHERMAL HEATING

& HEAT PUMPS

5,000

SOLAR HEATING BIOMASS FOSSIL

118

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.4.6 future investments in the heating sector

also in the heating sector the energy [r]evolution scenarios would require a major revision of current investment strategies in heating technologies. in particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. the use of biomass for heating purposes - often traditional biomass today - will be substantially reduced in the energy [r]evolution scenarios and replaced by more efficient and sustainable renewable heating technologies. renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. thus, it can only be roughly estimated that the energy [r]evolution scenario in total requires around Us$ 2,820 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) approximately Us$ 72 billion per year. the advanced scenario assumes an even more ambitious expansion of renewable technologies resulting in an average investment of around Us$ 76 billion per year, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with hydrogen or other synthetic fuels.

table 6.4.3 | oecd europe: installed capacities for renewable heat generation under the scenarios in

Biomass

ref e[r] adv

geotHermal

ref e[r] adv

solar Heating

ref e[r] adv

Heat PUmPs

ref e[r] adv

total*

ref e[r] adv

2012 419 419 419 2 2 2 32 32 32 30 30 30 482 482 482

2020 479 448 448 3 5 5 63 109 109 42 74 74 588 636 636

2030 530 417 417 5 37 37 104 517 517 56 245 245 695 1,216 1,216

2040 588 372 372 8 77 77 148 836 881 75 478 492 819 1,763 1,822

2050 645 322 322 9 85 100 202 1,021 1,087 101 611 631 957 2,039 2,140

* excluding direct electric heating.

figure 6.4.9 | oecd europe: development of investments for renewable heat generation technologies â&#x20AC;&#x201C; reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050

e[r] 2012-2050

BIOMASS,

53%

HEAT PUMPS,

GEOTHERMAL, SOLAR,

21%

TOTAL

adv e[r] 2012-2050

43%

TOTAL

990 BILLION USD 24%

GEOTHERMAL,

HEAT PUMPS,

46%

SOLAR,

43%

TOTAL

2,820 BILLION USD SOLAR,

BIOMASS,

2,965 BILLION USD HEAT PUMPS,

48%

119

world energy [r]evolution a sustainable world energy outlook

6.4.7 future employment in the energy sector

the advanced Energy [R]evolution scenario results in more energy sector jobs in oECD Europe at every stage of the projection.

figure 6.4.10 | oecd europe: employment in the energy sector under the reference and advanced energy [r]evolution scenarios

• there are 2 million energy sector jobs in the advanced energy [r]evolution in 2020, and 1.1 million in the reference scenario.

• in 2030, there are 2.7 million jobs in the advanced energy [r]evolution scenario and 1.1 million in the reference scenario. figure 6.4.10 shows the change in job numbers under both scenarios for each technology between 2015 and 2030. Jobs in the coal sector decline in both scenarios, and there is an overall decline of 12% in energy sector jobs in the reference scenario.

2.5 Direct jobs - Millions

• in 2025, there are 2.8 million jobs in the advanced energy [r]evolution scenario, and 1.1 million in the reference scenario.

3.0

strong growth in renewable energy leads to an increase of 62% in total energy sector jobs in the advanced energy [r]evolution scenario by 2020. Jobs continue to rise, and are more than double 2015 levels in both 2025 and 2030. renewable energy accounts for 86% of energy jobs by 2030, with solar heating having the greatest share (20%), followed by solar pV, wind, and biomass.

2.0

1.5

1.0

0.5

2015

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

& HEAT PUMP

- HEAT

2030

ADV E[R] WIND HYDRO

OCEAN

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

table 6.4.4 | oecd europe: total employment in the energy sector

2025

& DIESEL

in thousand jobs

advanced energy [r]evolution

reference

2015

2020

2025

2030

2020

2025

2030

294 152 84 725 1,255

253 153 82 631 1,120

228 149 81 662 1,121

209 139 80 654 1,083

246 140 96 1,547 2,029

177 143 101 2,330 2,751

135 134 110 2,363 2,742

203 144 380 528 1,255

125 92 402 501 1,120

142 92 405 483 1,121

135 76 407 465 1,083

560 508 443 518 2,029

1,001 725 535 489 2,751

934 732 623 453 2,742

jobs by fuel

coal gas, oil

diesel

nuclear renewables total jobs jobs by sector

construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs

120

energy

[r]evolution

6.4.8 transport table 6.4.5 | oecd europe: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in pj /a

a key target in oecd europe is to introduce incentives for people to drive smaller cars and buy new, more efficient vehicle concepts. in addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the metropolitan areas. along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the reference scenario. due to population increase, gdP growth and higher living standards, energy demand from the transport sector is expected to only slightly decrease in the reference scenario by around 6% to 12,700 PJ/a in 2050. in the basic energy [r]evolution scenario, efficiency measures and modal shifts will save 53% (6,700 PJ/a) in 2050 compared to the reference scenario.

rail

ref e[r] adv

road

ref e[r] adv

domestic aviation ref e[r] adv

additional modal shifts and technology switches lead to even higher energy savings in the advanced scenario of 60% (7,670 PJ/a) in 2050 compared to the reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. By 2030, electricity will provide 11% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the energy [r]evolution, while in 2050 the share will be 40% (51% in the advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. in 2050, more than 1,610 PJ/a of hydrogen is used in the transport sector for the advanced energy [r]evolution scenario.

domestic

ref

navigation

e[r] adv ref

total

e[r] adv

2012 387 387 387 12,527 12,527 12,527 262 262 262 238 238 238 13,414 13,414 13,414

2020 409 407 422 12,545 11,069 10,985 450 380 376 331 290 290 13,735 12,146 12,074

2030 417 417 570 12,557 8,157 7,451 491 410 385 331 265 265 13,796 9,249 8,671

2040 430 434 743 11,937 5,690 4,494 507 390 339 338 247 247 13,213 6,761 5,823

2050 442 446 866 11,328 4,925 3,617 518 370 296 341 240 240 12,629 5,980 5,019

figure 6.4.11 | oecd europe: final energy consumption in transport under the scenarios

16,000 14,000 12,000

PJ/a

10,000 8,000 EFFICIENCY

6,000

HYDROGEN ELECTRICITY

4,000

SYNFUELS BIOFUELS

2,000

NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

121

world energy [r]evolution a sustainable world energy outlook

6.4.10 development of co 2 emissions

CO2 emissions [Mt/a]

population (million)

4,000

700

3,500

600

3,000

500

2,500

With a 31% share of co 2, the industry sector will be the largest source of emissions in 2050 in the basic energy [r]evolution scenario. By 2050, oecd europe´s co 2 emissions are around 92% below 1990 levels in the energy [r]evolution scenario while energy consumption is fully decarbonised in the advanced case.

400

2,000 300

1,500

200

1,000

100

500 0

6.4.11 primary energy consumption

taking into account the assumptions discussed above, the resulting primary energy consumption under the energy [r]evolution scenarios is shown in figure 6.4.12. Under the basic energy [r]evolution scenario, primary energy demand will decrease by 44% from today’s 72,960 PJ/a to around 41,000 PJ/a. compared to the reference scenario, overall primary energy demand will be reduced by 46% in 2050 under the energy [r]evolution scenario (reference scenario: around 76,000 PJ in 2050). the advanced scenario results due to additional conversion losses in a primary energy consumption of around 42,400 PJ in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

of renewable energies and a fast introduction of very efficient vehicle concepts in the transport sector to replace oil based combustion engines. this leads to an overall renewable primary energy share of 37% in 2030 and 79% in 2050 in the basic energy [r]evolution and of more than 92% in 2050 in the advanced case (incl. non-energy consumption). in contrast to the reference scenario, no new nuclear power plants will be built in oecd europe in the energy [r]evolution scenarios.

the energy [r]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by expansion

figure 6.4.12 | oecd europe: projection of total primary energy demand (ped) by energy carrier including electricity including electricity import balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 90,000 80,000 70,000

EFFICIENCY OCEAN ENERGY

60,000

GEOTHERMAL

PJ/a

figure 6.4.13 | oecd europe: development of co2 emissions by sector under the energy [r]evolution scenarios ‘savings ’ = reduction compared to the reference scenario

Whilst oecd europe’s emissions of co 2 will decrease by 10% between 2012 and 2050 under the reference scenario, under the energy [r]evolution scenario they will decrease from 3,720 million tonnes in 2012 to 329 million tonnes in 2050. annual per capita emissions will drop from 6.6 tonne to 0.5 tonne. in spite of the abstinence of nuclear power production and increasing power demand, co 2 emissions will decrease in the electricity sector. in the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well.

50,000

SOLAR BIOMASS

40,000

WIND HYDRO

30,000

NATURAL GAS

20,000

CRUDE OIL COAL

10,000

NUCLEAR NET ELECTRICITY IMPORTS

122

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.4.6 | oecd europe: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

102.6 -198.0 -95.4

123.7 -659.0 -535.3

215.0 -812.6 -597.6

224.1 -789.4 -565.3

665.5 -2,459.2 -1,793.6

17.1 -63.1 -46.0

$ $ $ $ $ $

2.0 -21.3 16.1 4.6 13.4 14.7

28.3 179.6 122.7 42.5 84.7 457.8

24.8 760.1 224.0 59.2 144.1 1,212.2

11.4 1,416.8 273.6 58.9 165.7 1,926.4

66.5 2,335.2 636.5 165.1 407.9 3,611.2

1.7 59.9 16.3 4.2 10.5 92.6

average per year nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.4.7 | oecd europe: accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

26.5

429.1

657.4

713.2

1,826.2

2012 - 2050 average per year

46.8

table 6.4.8 | oecd europe: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs advanced e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

125.1 -224.2 -99.1

119.4 -1,011.8 -892.4

225.9 -1,256.5 -1,030.6

208.8 -1,274.7 -1,065.9

679.2 -3,767.3 -3,088.1

17.4 -96.6 -79.2

$ $ $ $ $ $

2.0 -21.3 16.6 4.6 13.4 15.2

28.3 186.3 125.3 42.5 84.7 467.1

24.8 807.4 228.5 59.2 144.1 1,264.0

11.4 1,521.5 276.2 58.9 165.7 2,033.7

66.5 2,494.0 646.6 165.1 407.9 3,780.0

1.7 63.9 16.6 4.2 10.5 96.9

average per year

nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative advanced e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.4.9 | accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs advanced e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

26.5

429.1

716.0

801.0

1,972.5

2012 - 2050 average per year

50.6

123

world energy [r]evolution a sustainable world energy outlook

6.5 africa this reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. the transformation to a carbon free energy system in the advanced scenario will further increase the electricity demand in 2050 up to 3,100 tWh/a. electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. around 490 tWh are used in 2050 for electric vehicles and rail transport in 2050 in the advanced scenario, around 560 tWh for hydrogen and 790 tWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.5.1 final energy demand by sector

efficiency gains in the heating sector are even larger than in the electricity sector. Under the energy [r]evolution scenarios, consumption equivalent to about 3,600 PJ/a is avoided through efficiency gains by 2050 compared to the reference scenario. as a result of the introduction of low energy standards and highly efficient technologies e.g. for industrial and commercial process heat, cooking and air conditioning, enjoyment of the same comfort and energy services will be accompanied by much lower future energy demand.

Under both energy [r]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.5.2). total electricity demand will rise from about 590 tWh/a to 2,890 tWh/a by 2050 in the basic energy [r]evolution scenario. compared to the reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 360 tWh/a.

figure 6.5.1 | africa: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat from chp autoproducers 50,000 45,000 40,000 35,000 30,000 PJ/a

combining the projections on population development, gdP growth and energy intensity results in future development pathways for africa’s final energy demand. these are shown in figure 6.5.1 for the reference and energy [r]evolution scenarios. Under the reference scenario, total final energy demand increases by 111% from the current 21,700 PJ/a to 45,700 PJ/a in 2050. in the basic energy [r]evolution scenario, final energy demand increases at a much lower rate by 26% compared to current consumption and is expected to reach 27,300 PJ/a by 2050. the advanced scenario results in some additional reductions due to a higher share of electric cars.

25,000 20,000 15,000 EFFICIENCY

10,000

OTHER SECTORS

5,000

INDUSTRY TRANSPORT

124

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.5.2 | africa: development of electricity demand by sector in the energy [r]evolution scenarios

figure 6.5.4 | africa: development of final energy demand for heat by sector in the energy [r]evolution scenarios 18,000

12,000

16,000 10,000

14,000 12,000 PJ/a

PJ/a

8,000

6,000

10,000 8,000 6,000

4,000

4,000 2,000

2,000 0

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.5.3 | africa: development of the final energy demand for transport by sector in the energy [r]evolution scenarios 12,000

10,000

PJ/a

8,000

6,000

4,000

2,000

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

125

world energy [r]evolution a sustainable world energy outlook

6.5.2 electricity generation

Hydro

ref e[r] adv

Biomass

ref e[r] adv

Wind

ref e[r] adv

geotHermal

ref e[r] adv

a 100% electricity supply from renewable energy resources in the advanced scenario leads to around 2,000 gW installed generation capacity in 2050.

ref e[r] adv

csP

table 6.5.1 shows the comparative evolution of the different renewable technologies in africa over time. Until 2020 hydro will remain the main renewable power source. By 2020 wind and Pv overtake biomass, currently the second largest contributor to the growing renewable market. after 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. the energy [r]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 38% to 45% by 2030 and 50% 2050. therefore, smart grids, demand side management (dsm), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

ref e[r] adv

ocean

ref e[r] adv

total

ref e[r] adv

2012 25 25 25 0 0 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 26 26 26

2020 38 34 34 2 4 5 5 23 26 1 1 1 6 28 31 1 7 7 0 0 0 54 96 104

2030 60 41 41 6 13 15 12 102 124 4 10 10 21 177 250 4 30 48 0 9 9 105 381 497

2040 86 47 47 9 15 21 19 220 333 9 20 20 40 423 598 11 113 199 0 25 45 175 863 1,264

2050 119 53 53 14 17 30 30 333 541 18 34 34 69 669 847 20 239 411 0 50 90 271 1,394 2,004

figure 6.5.5 | africa: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 7,000 OCEAN ENERGY

6,000

CSP GEOTHERMAL

5,000

TWh/a

table 6.5.1 | africa: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios in gw

the development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. this trend will more than compensate for the phasing out of nuclear power production in the energy [r]evolution scenarios, continuously reducing the number of fossil fuelfired power plants as well. By 2050, 95% of the electricity produced in africa will come from renewable energy sources in the basic energy [r]evolution scenario. ‘new’ renewables – mainly wind, Pv, csP and geothermal energy – will contribute 80% to the total electricity generation. already by 2020 the share of renewable electricity production will be 31% and 65% by 2030. the installed capacity of renewables will reach about 380 gW in 2030 and 1,390 gW by 2050.

BIOMASS PV

4,000

WIND HYDRO

3,000

HYDROGEN NUCLEAR

2,000

DIESEL OIL GAS

1,000

LIGNITE COAL

126

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.5.3 future costs of electricity generation

6.5.4 future investments in the power sector

figure 6.5.6 shows that the introduction of renewable technologies under both energy [r]evolution scenarios decreases the future costs of electricity generation compared to the reference scenario by 2030. the difference in full cost of generation will be around 1.4 Us$ct/kWh in the basic energy [r]evolution and around 1.3 Us$ct/kWh in the advanced scenario, without taking into account integration costs for storage or other load-balancing measures. Because of increasing prices for conventional fuels, electricity generation costs will become economically favourable starting just after 2020 under the energy [r]evolution scenarios. By 2050, the cost will be 2.8/2.1 Us$ct/kWh, respectively, below those in the reference case.

around Us$ 3,410 billion is required in investment for the energy [r]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 87 billion per year, Us$ 2,220 billion more than in the reference scenario (Us$ 1,190 billion). investments for the advanced scenario sum up to Us$ 4,890 billion until 2050, on average Us$ 125 billion per year. Under the reference scenario, the levels of investment in conventional power plants add up to almost 42% while approximately 58% would be invested in renewable energies and cogeneration until 2050.

Under the reference scenario, on the other hand, growth in demand and increasing fossil fuel prices result in total electricity supply costs rising from todayâ&#x20AC;&#x2122;s Us$ 67 billion per year to more than Us$ 277 billion in 2050, compared to Us$ 326 billion in the basic and Us$ 507 billion in the advanced energy [r]evolution scenario. figure 6.5.6 shows that both energy [r]evolution scenarios not only comply with africaÂ´s co 2 reduction targets, but also help stabilise energy costs and relieve the economic pressure on society. increasing energy efficiency and shifting energy supply to renewables lead to long term total costs for electricity supply that are only 18% higher in the basic energy [r]evolution scenario than in the reference scenario, despite a 57% increase in electricity production. the advanced scenario with 100% renewable power and more than a doubling of generation results in supply costs 83% higher than the reference case.

figure 6.5.6 | africa: development of total electricity supply costs & of specific electricity generation costs in the scenarios Billion $

Under the energy [r]evolution scenarios, however, africa would shift almost 95%/96% of the entire investment towards renewables and cogeneration, respectively. By 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants. Because renewable energy has no fuel costs, the fuel cost savings in the basic energy [r]evolution scenario reach a total of Us$ 2,500 billion up to 2050, Us$ 64 billion per year. the total fuel cost savings therefore would cover 110% of the total additional investments compared to the reference scenario. fuel cost savings in the advanced scenario are even higher and add up to Us$ 2,670 billion, or Us$ 68 billion per year. renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.5.7 | africa: investment shares reference versus energy [r]evolution scenarios

US$ct/kWh

600

500

FOSSIL,

39% 56%

RENEWABLE,

ref 2012-2050

TOTAL

1,190 BILLION USD

400

300

200

NUCLEAR, CHP, 2%

FOSSIL, 5% CHP, 4%

e[r] 2012-2050

TOTAL

3,400 BILLION

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

RENEWABLE,

91%

USD

100

FOSSIL, 4% CHP, 3%

adv e[r] 2012-2050

TOTAL

4,890 BILLION

RENEWABLE,

93%

USD

127

world energy [r]evolution a sustainable world energy outlook

6.5.5 energy supply for heating

Biomass

ref e[r] adv

solar Heating

ref e[r] adv

geotHermal Heat ref

• energy efficiency measures help to reduce the currently growing energy demand for heating and cooking by 21% in 2050 (relative to the reference scenario), in spite of improving living standards and economic growth.

and Heat PUmPs

total

e[r] adv

Hydrogen

ref e[r] adv ref e[r] adv

2012 4,334 4,334 4,334 5 5 5 0 0 0 0 0 0 4,339 4,339 4,339

2020 5,796 5,185 5,185 33 203 203 0 94 94 0 0 0 5,830 5,482 5,482

2030 6,354 5,346 5,346 50 701 701 0 213 213 0 0 0 6,403 6,260 6,260

2040 7,349 5,664 5,690 104 1,819 1,819 0 558 570 0 56 387 7,454 8,098 8,464

2050 8,180 5,213 5,540 186 3,336 3,315 0 944 992 0 379 914 8,366 9,871 10,760

• a shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of co 2 emissions. table 6.5.8 shows the development of different renewable technologies for heating in africa over time. although biomass remains the main contributor, its market share is decrasing and with it unefficient traditional biomass. after 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will further reduce the dependence on fossil fuels. the advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.5.8 | africa: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 18,000 16,000 14,000 12,000

PJ/a

table 6.5.2 | africa: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in pj /a

today, traditional biomass use meets around 60% of africa’s energy demand for heat. incentives to move to improved and modern biomass technologies are vital to enhance efficiency and to keep biomass consumption in check. dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. in the basic energy [r]evolution scenario, renewables already provide 68% of africa’s total heat demand in 2030 and 91% in 2050.

10,000 8,000

EFFICIENCY

6,000

ELECTRIC HEATING

4,000

& HEAT PUMPS

HYDROGEN

GEOTHERMAL HEATING

SOLAR HEATING

2,000

BIOMASS FOSSIL

128

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.5.6 future investments in the heating sector

also in the heating sector the energy [r]evolution scenarios would require a major revision of current investment strategies in heating technologies. in particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. the use of biomass for heating purposes - often traditional biomass today - will be substantially reduced in the energy [r]evolution scenarios and replaced by more efficient and sustainable renewable heating technologies. renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. thus, it can only be roughly estimated that the energy [r]evolution scenario in total requires around Us$ 610 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 16 billion per year. the advanced scenario assumes an equally ambitious expansion of renewable technologies, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with electricity, hydrogen or other synthetic fuels.

table 6.5.3 | africa: installed capacities for renewable heat generation under the scenarios

Biomass

ref e[r] adv

geotHermal

ref e[r] adv

solar Heating

ref e[r] adv

Heat PUmPs

ref e[r] adv

total*

ref e[r] adv

2012 3,736 3,736 3,736 0 0 0 1 1 1 0 0 0 3,736 3,736 3,736

2020 4,297 3,697 3,697 0 2 2 4 9 9 0 0 0 4,300 3,708 3,708

2030 4,635 3,259 3,259 0 8 8 10 144 144 0 13 13 4,645 3,425 3,425

2040 4,640 2,874 2,874 0 13 13 21 374 374 0 44 44 4,661 3,305 3,304

2050 4,550 2,124 2,245 0 18 18 38 685 685 0 88 88 4,588 2,917 3,033

* excluding direct electric heating.

figure 6.5.9 | africa: development of investments for renewable heat generation technologies â&#x20AC;&#x201C; reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050 SOLAR,

e[r] 2012-2050

adv e[r] 2012-2050

BIOMASS,

31%

HEAT PUMPS, TOTAL

710 BILLION USD

BIOMASS,

98%

BIOMASS,

26%

TOTAL

31%

HEAT PUMPS,

26%

GEOTHERMAL,

TOTAL

610 BILLION USD

600 BILLION USD GEOTHERMAL, SOLAR,

34%

SOLAR,

34%

129

world energy [r]evolution a sustainable world energy outlook

6.5.7 future employment in the energy sector

the advanced Energy [R]evolution scenario results in more energy sector jobs in africa from 2025 onwards.

figure 6.5.10 | africa: employment in the energy sector under the reference and advanced energy [r]evolution scenario

• at 2020, there are 7.6 million energy sector jobs in both the advanced energy [r]evolution and the reference scenario.

12.0

• in 2025, there are 8.7 million jobs in the advanced energy [r]evolution scenario, and 8.2 million in the reference scenario. • in 2030, there are 9.4 million jobs in the advanced energy [r]evolution scenario and 8.6 million in the reference scenario. figure 6.5.10 shows the change in job numbers under both scenarios for each technology between 2015 and 2030. Jobs in the reference scenario increase by 24% by 2030. bionergy accounts for by far the largest share of jobs in both scenarios.

Direct jobs - Millions

10.0

the non-biomass renewable energy grows strongly in the advanced energy [r]evolution scenario. until 2020 this offsets declines in bioenergy, so job levels are very close to the reference scenario. non-biomass renewable energy continues to grow strongly until 2030, when it is 35% above 2015 numbers. renewable energy accounts for 98% of energy sector jobs by 2030.

table 6.5.4 | africa: total employment in the energy sector

8.0

6.0

4.0

2.0

2015

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

& HEAT PUMP

- HEAT

2025

2030

ADV E[R] WIND HYDRO

OCEAN

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

& DIESEL

in thousand jobs

advanced energy [r]evolution

reference

2015

2020

2025

2030

2020

2025

2030

314 197 12 6,454 6,977

328 217 18 7,166 7,729

332 233 21 7,589 8,175

357 249 23 7,971 8,600

102 155 6 7,289 7,552

72 166 7 8,458 8,703

39 155 6 9,200 9,400

297 129 183 6,315 52 6,977

356 144 241 6,930 58 7,729

350 145 300 7,313 67 8,175

373 160 323 7,668 76 8,600

791 197 354 6,175 35 7,552

1,656 503 615 5,900 29 8,703

2,268 863 948 5,298 24 9,400

jobs by fuel

coal gas, oil

diesel

nuclear renewables total jobs jobs by sector

construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs

130

energy

[r]evolution

6.5.8 transport table 6.5.5 | africa: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in pj /a

in 2050, the car fleet in africa will be significantly larger than today. today, a large share of old cars are driven in africa. With growing individual mobility, an increasing share of small efficient cars is projected in the energy[r]evolution scenarios. due to population increase, gdP growth and higher living standards, energy demand from the transport sector is expected to increase in the reference scenario by around 170% to 10,400 PJ/a in 2050. in the basic energy [r]evolution scenario, efficiency measures and modal shifts will save 43% (4,500 PJ/a) in 2050 compared to the reference scenario.

rail

ref e[r] adv

road

ref e[r] adv

domestic aviation ref e[r]

additional modal shifts and technology switches lead to even higher energy savings in the advanced scenario of 51% (5,260 PJ/a) in 2050 compared to the reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. By 2030, electricity will provide 3% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the energy [r]evolution, while in 2050 the share will be 25% (35% in the advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. in 2050, up to 1,540 PJ/a of hydrogen is used in the transport sector for the advanced energy [r]evolution scenario.

adv domestic

ref

navigation

e[r] adv ref

total

e[r] adv

2012 30 30 30 3,143 3,143 3,143 107 107 107 28 28 28 3,307 3,307 3,307

2020 35 45 56 5,110 4,131 4,072 140 125 125 30 45 45 5,315 4,346 4,298

2030 37 56 113 5,786 4,663 4,324 170 150 148 31 62 62 6,023 4,931 4,648

2040 39 64 162 7,839 4,991 4,323 275 194 190 31 81 81 8,184 5,330 4,757

2050 42 94 283 9,881 5,436 4,501 389 244 229 32 89 89 10,345 5,863 5,103

figure 6.5.11 | africa: final energy consumption in transport under the scenarios

12,000

10,000

PJ/a

8,000

6,000 EFFICIENCY HYDROGEN

4,000

ELECTRICITY SYNFUELS

2,000

BIOFUELS NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

131

world energy [r]evolution a sustainable world energy outlook

6.5.10 development of co 2 emissions

CO2 emissions [Mt/a]

population (million)

3,000

2,500

2,000

2,000 1,500 1,500 1,000 1,000 500

500

6.5.11 primary energy consumption

taking into account the assumptions discussed above, the resulting primary energy consumption under the energy [r]evolution scenarios is shown in figure 6.5.12. Under the basic energy [r]evolution scenario, primary energy demand will increase by 19% from today’s 30,970 PJ/a to around 37,000 PJ/a compared to the reference scenario, overall primary energy demand will be reduced by 44% in 2050 under the energy [r]evolution scenario (reference: around 367,000 PJ in 2050). the advanced scenario results due to additional conversion losses in a primary energy consumption of around 39,500 PJ in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

very efficient vehicle concepts in the transport sector to replace oil based combustion engines. this leads to an overall renewable primary energy share of 56% in 2030 and 81% in 2050 in the basic energy [r]evolution and of more than 97% in 2050 in the advanced case (incl. non-energy consumption). in contrast to the reference scenario, no new nuclear power plants will be built in africa in the energy [r]evolution scenarios.

the energy [r]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by expansion of renewable energies and a fast introduction of

figure 6.5.12 | africa: projection of total primary energy demand (ped) by energy carrier including electricity including electricity import balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 70,000

60,000 NET ELECTRICITY IMPORTS

50,000

EFFICIENCY OCEAN ENERGY

40,000

GEOTHERMAL

PJ/a

figure 6.5.13 | africa: development of co 2 emissions by sector under the energy [r]evolution scenarios ‘ savings ’ = reduction compared to the reference scenario

Whilst africa`s emissions of co 2 will increase by 149% between 2012 and 2050 under the reference scenario, under the energy [r]evolution scenario they will decrease from 1,050 million tonnes in 2012 to 363 million tonnes in 2050. annual per capita emissions will drop from 1 tonne to 0.2 tonne. in spite of the abstinence of nuclear power production and increasing power demand, co 2 emissions will decrease in the electricity sector. in the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well. With a 57% share of co 2, the transport sector will be the largest source of emissions in 2050 in the basic e[r] scenario. By 2050, africa´s co 2 emissions are 33% below 1990 levels in the energy [r]evolution scenario while energy consumption is fully decarbonised in the advanced case.

SOLAR

30,000

BIOMASS WIND

20,000

HYDRO NATURAL GAS CRUDE OIL

10,000

COAL NUCLEAR

132

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.5.6 | africa: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

31.6 -85.8 -54.2

73.7 -514.8 -441.0

102.9 -839.3 -736.4

123.4 -1,116.8 -993.4

331.5 -2,556.6 -2,225.1

8.5 -65.6 -57.1

$ $ $ $ $ $

17.0 7.6 8.6 0.0 0.2 33.3

88.0 153.0 87.5 0.0 2.6 331.0

124.9 477.6 209.6 0.0 6.5 818.7

130.5 831.7 340.9 0.0 12.4 1,315.5

360.4 1,470.0 646.6 0.0 21.7 2,498.6

9.2 37.7 16.6 0.0 0.6 64.1

average per year nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.5.7 | accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

-156.6

-186.9

81.7

158.1

-103.7

2012 - 2050 average per year

-2.7

table 6.5.8 | africa: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs advanced e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

35.7 -103.5 -67.7

82.8 -707.9 -625.1

81.8 -1,450.7 -1,368.9

92.9 -1,734.6 -1,641.7

293.3 -3,996.7 -3,703.3

7.5 -102.5 -95.0

$ $ $ $ $ $

17.0 7.6 10.5 0.0 0.2 35.2

88.0 153.0 110.3 0.0 2.6 353.9

124.9 518.1 226.0 0.0 6.5 875.6

130.5 921.6 338.9 0.0 12.4 1,403.4

360.4 1,600.3 685.6 0.0 21.7 2,668.0

9.2 41.0 17.6 0.0 0.6 68.4

average per year

nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative advanced e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.5.9 | africa: accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs advanced e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

-156.6

-186.9

80.9

152.3

-110.3

2012 - 2050 average per year

-2.8

133

world energy [r]evolution a sustainable world energy outlook

6.6 middle east this reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. the transformation to a carbon free energy system in the advanced scenario will further increase the electricity demand in 2050 up to 2,700 tWh/a. electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. around 650 tWh are used in 2050 for electric vehicles and rail transport in 2050 in the advanced scenario, around 650 tWh for hydrogen and 60 tWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.6.1 final energy demand by sector

efficiency gains in the heating sector are even larger than in the electricity sector. Under the energy [r]evolution scenarios, consumption equivalent to about 6,600 PJ/a is avoided through efficiency gains by 2050 compared to the reference scenario. as a result of the introduction of low energy standards and highly efficient technologies e.g. for industrial and commercial process heat, cooking and air conditioning, enjoyment of the same comfort and energy services will be accompanied by much lower future energy demand.

Under both energy [r]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.6.2). total electricity demand will rise from about 730 tWh/a to 2,440 tWh/a by 2050 in the basic energy [r]evolution scenario. compared to the reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 810 tWh/a.

figure 6.6.1 | middle east: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat from chp autoproducers 40,000 35,000 30,000 25,000 PJ/a

combining the projections on population development, gdP growth and energy intensity results in future development pathways for middle east’s final energy demand. these are shown in figure 6.6.1 for the reference and energy [r]evolution scenarios. Under the reference scenario, total final energy demand increases by 134% from the current 15,300 PJ/a to 35,800 PJ/a in 2050. in the basic energy [r]evolution scenario, final energy demand increases at a much lower rate by 12% compared to current consumption and is expected to reach 17,200 PJ/a by 2050. the advanced scenario results in some additional reductions due to a higher share of electric cars.

20,000 15,000 10,000

EFFICIENCY OTHER SECTORS

5,000

INDUSTRY TRANSPORT

134

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.6.4 | middle east: development of final energy demand for heat by sector in the energy [r]evolution scenarios

figure 6.6.2 | middle east: development of electricity demand by sector in the energy [r]evolution scenarios

16,000

12,000

14,000

10,000

12,000 10,000 PJ/a

PJ/a

8,000

6,000

8,000 6,000

4,000

4,000 2,000

2,000 0

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.6.3 | middle east: development of the final energy demand for transport by sector in the energy [r]evolution scenarios 14,000 12,000 10,000

PJ/a

8,000 6,000 4,000 2,000 0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

135

world energy [r]evolution a sustainable world energy outlook

6.6.2 electricity generation

Hydro

ref e[r] adv

Biomass

ref e[r] adv

Wind

ref e[r] adv

geotHermal

ref e[r]

a 100% electricity supply from renewable energy resources in the advanced scenario leads to around 1,510 gW installed generation capacity in 2050.

adv Pv

ref e[r] adv

table 6.6.1 shows the comparative evolution of the different renewable technologies in middle east over time. By 2020 wind and Pv overtake hydro, currently the largest contributor to the growing renewable market. after 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. the energy [r]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 28% to 34% by 2030 and 45% to 41% by 2050. therefore, smart grids, demand side management (dsm), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

csP

ref e[r] adv

ocean

ref e[r] adv

total

ref e[r] adv

2012 14 14 14 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 15 15 15

2020 18 18 18 0 2 2 1 16 21 0 1 2 3 34 34 2 10 10 0 2 2 24 83 89

2030 23 23 23 1 5 5 5 82 107 0 6 6 9 151 223 5 86 109 0 7 7 44 360 480

2040 26 26 26 3 7 6 19 130 229 0 14 14 19 358 449 8 167 242 0 17 30 75 719 996

figure 6.6.5 | middle east: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 5,000 4,500

OCEAN ENERGY CSP

4,000

GEOTHERMAL

3,500

BIOMASS PV

3,000 TWh/a

table 6.6.1 | middle east: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios in gw

the development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. this trend will more than compensate for the strong reduction of fossil fuel fired power plants in the energy [r]evolution scenarios. By 2050, 93% of the electricity produced in middle east will come from renewable energy sources in the basic energy [r]evolution scenario. ‘new’ renewables – mainly wind, Pv, csP and geothermal energy – will contribute 86% to the total electricity generation. already by 2020 the share of renewable electricity production will be 14% and 52% by 2030. the installed capacity of renewables will reach about 360 gW in 2030 and 1,170 gW by 2050.

WIND

2,500

HYDRO HYDROGEN

2,000

NUCLEAR

2,500

DIESEL OIL

1,500

GAS

500

LIGNITE COAL

136

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2050 30 30 30 7 9 8 45 188 285 0 15 22 35 656 722 7 245 394 0 26 46 124 1,168 1,505

energy

[r]evolution

6.6.3 future costs of electricity generation

6.6.4 future investments in the power sector

figure 6.6.6 shows that the introduction of renewable technologies under both energy [r]evolution scenarios decreases the future costs of electricity generation compared to the reference scenario by 2030. this difference in full cost of generation will be less than 2.8 Us$ct/kWh in the basic energy [r]evolution and about 3 Us$ct/kWh in the advanced scenario, without taking into account integration costs for storage or other load-balancing measures. Because of increasing prices for conventional fuels, electricity generation costs will become economically favourable in the future under the energy [r]evolution scenarios. By 2050, the cost will be 6.8/5.8 Us$ct/kWh, respectively, below those in the reference case.

around Us$ 3,400 billion is required in investment for the energy [r]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 87 billion per year, Us$ 2,570 billion more than in the reference scenario (Us$ 835 billion). investments for the advanced scenario sum up to Us$ 4,700 billion until 2050, on average Us$ 121 billion per year. Under the reference scenario, the levels of investment in conventional power plants add up to almost 64% while approximately 36% would be invested in renewable energies and cogeneration until 2050.

Under the reference scenario, on the other hand, growth in demand and increasing fossil fuel prices result in total electricity supply costs rising from todayâ&#x20AC;&#x2122;s Us$ 138 billion per year to more than Us$ 379 billion in 2050, compared to Us$ 302 billion in the basic and Us$ 453 billion in the advanced energy [r]evolution scenario. figure 6.6.6 shows that both energy [r]evolution scenarios not only comply with middle eastÂ´s co 2 reduction targets, but also help stabilise energy costs and relieve the economic pressure on society. increasing energy efficiency and shifting energy supply to renewables lead to long term costs for electricity supply that are 20% lower in the basic energy [r]evolution scenario than in the reference scenario despite a 40% increase in electricity production. the advanced scenario with 100% renewable power and an increase in power generation of 89% results in supply costs 20% higher than the reference case.

figure 6.6.6 | middle east: development of total electricity supply costs & of specific electricity generation costs in the scenarios Billion $

Under the energy [r]evolution scenarios, however, middle east would shift almost 93%/96% of the entire investment towards renewables and cogeneration, respectively. By 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants. Because renewable energy has no fuel costs, the fuel cost savings in the basic energy [r]evolution scenario reach a total of Us$ 4,270 billion up to 2050, Us$ 109 billion per year. the total fuel cost savings therefore would cover 170% of the total additional investments compared to the reference scenario. fuel cost savings in the advanced scenario are even higher and add up to Us$ 4,570 billion, or Us$ 117 billion per year. renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.6.7 | middle east: investment shares reference versus energy [r]evolution scenarios

US$ct/kWh

600

FOSSIL,

20 18

500

ref 2012-2050

TOTAL

835 BILLION USD

CHP, 1% NUCLEAR,

400

FOSSIL, 7% CHP, 1%

300

59% 35%

RENEWABLE,

8 200

e[r] 2012-2050

RENEWABLE,

92%

USD

100

TOTAL

3,400 BILLION

2 0

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

FOSSIL, 4% CHP, 1%

adv e[r] 2012-2050

TOTAL

4,700 BILLION

RENEWABLE,

95%

USD

137

world energy [r]evolution a sustainable world energy outlook

6.6.5 energy supply for heating table 6.6.2 | middle east: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in pj /a

today, renewables meet around 1% of middle east’s energy demand for heating, the main contribution coming from the use of biomass. dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. in the basic energy [r]evolution scenario, renewables already provide 24% of middle east’s total heat demand in 2030 and 78% in 2050.

ref e[r] adv

solar Heating

ref e[r]

• energy efficiency measures help to reduce the currently growing energy demand for heating and processes by 43 % in 2050 (relative to the reference scenario), in spite of improving living standards and economic growth.

adv geotHermal Heat ref and Heat PUmPs

e[r] adv

Hydrogen

ref e[r] adv ref

total

e[r] adv

2012 20 20 20 7 7 7 0 0 0 0 0 0 27 27 27

2020 131 152 152 40 370 370 0 287 287 0 3 3 171 813 813

2030 188 187 187 55 733 733 0 383 383 0 6 6 243 1,310 1,310

2040 350 302 302 94 1,609 1,609 0 722 722 0 17 188 445 2,649 2,820

2050 569 511 511 149 2,020 2,386 0 1,287 1,287 0 312 1,258 719 4,130 5,442

• a shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of co 2 emissions. table 6.6.2 shows the development of different renewable technologies for heating in middle east over time. By 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will reduce the dependence on fossil fuels. the advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.6.8 | middle east: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 16,000 14,000 12,000 10,000 PJ/a

Biomass

8,000 EFFICIENCY HYDROGEN

6,000

ELECTRIC HEATING

4,000

GEOTHERMAL HEATING

& HEAT PUMPS

SOLAR HEATING

2,000

BIOMASS FOSSIL

138

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.6.6 future investments in the heating sector

also in the heating sector the energy [r]evolution scenarios would require a major revision of current investment strategies in heating technologies. in particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. the use of biomass for heating purposes - often traditional biomass today - will be redirected towards new efficient technologies in the energy [r]evolution scenarios and supplement other sustainable renewable heating technologies. renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. thus, it can only be roughly estimated that the energy [r]evolution scenario in total requires around Us$ 430 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 11 billion per year. the advanced scenario assumes an equally ambitious expansion of renewable technologies resulting in an average investment of around Us$ 12 billion per year, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with electricity, hydrogen or other synthetic fuels.

table 6.6.3 | middle east: installed capacities for renewable heat generation under the scenarios in

Biomass

ref e[r] adv

geotHermal

ref e[r] adv

solar Heating

ref e[r] adv

Heat PUmPs

ref e[r] adv

total*

ref e[r] adv

2012 5 5 5 0 0 0 1 1 1 0 0 0 6 6 6

2020 12 20 20 0 10 10 5 31 31 0 7 7 17 68 68

2030 28 26 26 0 17 17 10 117 117 0 16 16 38 176 176

2040 47 34 34 0 21 21 18 254 254 0 36 36 65 345 345

2050 70 46 46 0 34 34 28 302 341 0 81 81 98 464 502

* excluding direct electric heating.

figure 6.6.9 | middle east: development of investments for renewable heat generation technologies â&#x20AC;&#x201C; reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050 SOLAR,

e[r] 2012-2050

adv e[r] 2012-2050

BIOMASS,

10%

GEOTHERMAL, HEAT PUMPS, TOTAL

TOTAL

61 BILLION USD

90%

24%

10%

GEOTHERMAL,

36%

HEAT PUMPS,

21% 33%

TOTAL

433 BILLION USD

BIOMASS,

473 BILLION USD SOLAR,

30%

SOLAR,

36%

139

world energy [r]evolution a sustainable world energy outlook

6.6.7 future employment in the energy sector

the advanced Energy [R]evolution scenario results in more energy sector jobs in the Middle East at every stage of the projection.

figure 6.6.10 | middle east: employment in the energy sector under the reference and advanced energy [r]evolution scenario

• there are 0.9 million energy sector jobs in the advanced energy [r]evolution in 2020, and 0.6 million in the reference scenario.

• in 2030, there are 1.1 million jobs in the advanced energy [r]evolution scenario and 0.6 million in the reference scenario. figure 6.6.10 shows the change in job numbers under both scenarios for each technology between 2015 and 2030. Jobs in the reference scenario increase gradually to 17% above 2015 levels by 2030. gas accounts for 89% of energy sector jobs in this scenario.

1.0 Direct jobs - Millions

• in 2025, there are 1.1 million jobs in the advanced energy [r]evolution scenario, and 0.6 million in the reference scenario.

1.2

0.8

0.6

0.4

0.2

2015

growth in renewable energy leads to an increase of 67% in total energy sector jobs in the advanced energy [r]evolution scenario by 2020, and compensates for a strong decline in gas jobs. Jobs remain stable after 2025, and are 106% above 2015 levels in 2030. renewable energy accounts for 71% of energy jobs at 2030, with pV having the greatest share.

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

table 6.6.4 | middle east: total employment in the energy sector

& HEAT PUMP

- HEAT

2025

2030

ADV E[R] WIND HYDRO

OCEAN

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

& DIESEL

in thousand jobs

energy [r]evolution

reference

2015

2020

2025

2030

2020

2025

2030

3 477 8 30 518

2 519 11 42 574

2 546 10 52 610

2 537 8 60 606

1 445 0 416 862

1 388 0 674 1,064

1 312 0 750 1,064

37 17 59 318 86 518

42 17 71 361 83 574

40 16 80 397 77 610

34 12 82 410 68 606

266 74 104 339.1 79 862

422 95 170 316 60 1,064

388 90 267 276 42 1,064

jobs by fuel

coal gas, oil

diesel

nuclear renewables total jobs jobs by sector

construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs

140

energy

[r]evolution

6.6.8 transport table 6.6.5 | middle east: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in pj /a

a key target in middle east is to introduce incentives for people to drive smaller cars and buy new, more efficient vehicle concepts. in addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the expanding urban areas. along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the reference scenario. due to population increase, gdP growth and higher living standards, energy demand from the transport sector is expected to increase in the reference scenario by around 140% to 12,680 PJ/a in 2050. in the basic energy [r]evolution scenario, efficiency measures and modal shifts will save 59% (7,530 PJ/a) in 2050 compared to the reference scenario.

rail

ref e[r] adv

road

ref e[r] adv

domestic aviation ref e[r] adv

additional modal shifts and technology switches lead to even higher energy savings in the advanced scenario of 63% (7,950 PJ/a) in 2050 compared to the reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. By 2030, electricity will provide 8% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the energy [r]evolution, while in 2050 the share will be 40% (49% in the advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. in 2050, up to 1,810 PJ/a of hydrogen is used in the transport sector for the advanced energy [r]evolution scenario.

domestic

ref

navigation

e[r] adv ref

total

e[r] adv

2012 2 2 2 5,226 5,226 5,226 46 46 46 0 0 0 5,275 5,275 5,275

2020 2 3 20 8,197 6,717 6,642 76 53 53 0 0 0 8,276 6,773 6,716

2030 2 4 60 9,565 6,515 6,031 84 65 65 0 0 0 9,651 6,583 6,156

2040 2 3 88 11,673 5,787 5,126 116 80 80 0 0 0 11,792 5,871 5,295

2050 2 5 89 12,486 5,053 4,550 154 85 85 0 0 0 12,642 5,142 4,724

figure 6.6.11 | middle east: final energy consumption in transport under the scenarios

14,000

12,000

10,000

PJ/a

8,000

6,000

EFFICIENCY HYDROGEN

4,000

ELECTRICITY SYNFUELS BIOFUELS

2,000

NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

141

world energy [r]evolution a sustainable world energy outlook

6.6.10 development of co 2 emissions

CO2 emissions [Mt/a]

population (million)

3,500

350

3,000

300

2,500

250

2,000

200

1,500

150

2,000

100

1,500

6.6.11 primary energy consumption

taking into account the assumptions discussed above, the resulting primary energy consumption under the energy [r]evolution scenarios is shown in figure 6.6.12. Under the basic energy [r]evolution scenario, primary energy demand will decrease by 8% from today’s 28,270 PJ/a to around 26,000 PJ/a. compared to the reference scenario, overall primary energy demand will be reduced by 55% in 2050 under the energy [r]evolution scenario (reference scenario: around 58,000 PJ in 2050). due to additional conversion losses, the advanced scenario results in a primary energy consumption of around 27,300 PJ in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

very efficient vehicle concepts in the transport sector to replace oil based combustion engines. this leads to an overall renewable primary energy share of 20% in 2030 and 66% in 2050 in the basic energy [r]evolution and of more than 85% in 2050 in the advanced case (incl. non-energy consumption). in contrast to the reference scenario, no new nuclear power plants will be built in middle east in the energy [r]evolution scenarios.

the energy [r]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by expansion of renewable energies and a fast introduction of

figure 6.6.12 | middle east: projection of total primary energy demand (ped) by energy carrier including electricity including electricity import balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 60,000

50,000 EFFICIENCY OCEAN ENERGY

40,000

GEOTHERMAL

PJ/a

figure 6.6.13 | middle east: development of co2 emissions by sector under the energy [r]evolution scenarios ‘savings ’ = reduction compared to the reference scenario

Whilst middle east’s emissions of co2 will double between 2012 and 2050 under the reference scenario, under the energy [r]evolution scenario they will decrease from 1,670 million tonnes in 2012 to 294 million tonnes in 2050. annual per capita emissions will drop from 7.7 tonne to 0.8 tonne. in spite of the abstinence of nuclear power production and increasing power demand, co2 emissions will decrease in the electricity sector. in the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well. With a 32% share of co2, the Power generation sector will be the largest source of emissions in 2050 in the basic energy [r]evolution scenario. By 2050, middle east´s co2 emissions are 47% below 1990 levels in the energy [r]evolution scenario while energy consumption is fully decarbonised in the advanced case.

SOLAR

30,000

BIOMASS WIND HYDRO

20,000

NATURAL GAS CRUDE OIL

10,000

COAL NUCLEAR NET ELECTRICITY IMPORTS

142

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.6.6 | middle east: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

37.0 -152.2 -115.2

90.2 -759.0 -668.8

63.1 -849.3 -786.1

113.2 -1,115.2 -1,002.1

303.5 -2,875.7 -2,572.2

7.8 -73.7 -66.0

$ $ $ $ $ $

46.6 26.8 0.7 0 0.7 74.8

251.7 432.3 2.5 0 5.6 692.0

360.1 1,120.1 3.7 0 11.4 1,495.2

303.3 1,683.5 5.0 0 17.2 2,009.0

961.6 3,262.7 11.9 0 34.9 4,271.1

24.7 83.7 0.3 0 0.9 109.5

average per year nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.6.7 | middle east: accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

59.7

60.3

120.7

131.3

372.0

2012 - 2050 average per year

9.5

table 6.6.8 | middle east: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs advanced e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

38.6 -173.5 -134.9

78.8 -1,015.4 -936.6

69.3 -1,337.8 -1,268.5

153.3 -1,684.6 -1,531.3

340.0 -4,211.2 -3,871.2

8.7 -108.0 -99.3

$ $ $ $ $ $

46.6 29.9 0.7 0 0.7 77.8

257.6 466.2 2.6 0 5.6 732.0

373.9 1,210.8 3.7 0 11.4 1,599.8

307.4 1,830.9 5.0 0 17.2 2,160.5

985.4 3,537.8 12.0 0 34.9 4,570.2

25.3 90.7 0.3 0 0.9 117.2

average per year

nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative advanced e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.6.9 | middle east: accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs advanced e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

59.7

60.3

120.7

171.1

411.8

2012 - 2050 average per year

10.6

143

world energy [r]evolution a sustainable world energy outlook

6.7 eastern europe/eurasia this reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. the transformation to a carbon free energy system in the advanced scenario will further increase the electricity demand in 2050 up to 2,500 tWh/a. electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. around 580 tWh are used in 2050 for electric vehicles and rail transport in 2050 in the advanced scenario, around 170 tWh for hydrogen and 150 tWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.7.1 final energy demand by sector

efficiency gains in the heating sector are even larger than in the electricity sector. Under the energy [r]evolution scenarios, consumption equivalent to about 11,700 PJ/a is avoided through efficiency gains by 2050 compared to the reference scenario. as a result of energy-related renovation of the existing stock of residential buildings, the introduction of low energy standards and ‘passive climatisation’ for new buildings, as well as highly efficient air conditioning systems, enjoyment of the same comfort and energy services will be accompanied with much lower future energy demand.

Under both energy [r]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.7.2). total electricity demand will rise from about 1,250 tWh/a to 2,360 tWh/a by 2050 in the basic energy [r]evolution scenario. compared to the reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 870 tWh/a.

figure 6.7.1 | eastern europe/eurasia: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat from chp autoproducers 45,000 40,000 35,000 30,000

PJ/a

combining the projections on population development, gdP growth and energy intensity results in future development pathways for eastern europe/eurasia’s final energy demand. these are shown in figure 6.7.1 for the reference and energy [r]evolution scenarios. Under the reference scenario, total final energy demand increases by 53% from the current 27,400 PJ/a to 41,800 PJ/a in 2050. in the basic energy [r]evolution scenario, final energy demand decreases by 19% compared to current consumption and is expected to reach 22,100 PJ/a by 2050 the advanced scenario results in some additional reductions due to a higher share of electric cars.

25,000 20,000 15,000 10,000

EFFICIENCY OTHER SECTORS

5,000

INDUSTRY TRANSPORT

144

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.7.2 | eastern europe/eurasia:development of electricity demand by sector in the energy [r]evolution scenarios

figure 6.7.4 | eastern europe/eurasia:development of final energy demand for heat by sector in the energy [r]evolution scenarios 30,000

10,000 9,000

25,000

8,000 7,000

20,000 PJ/a

PJ/a

6,000 5,000 4,000

15,000

10,000

3,000 2,000

5,000

1,000 0

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.7.3 | eastern europe/eurasia:development of the final energy demand for transport by sector in the energy [r]evolution scenarios 8,000 7,000 6,000

PJ/a

5,000 4,000 3,000 2,000 1,000 0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

145

world energy [r]evolution a sustainable world energy outlook

6.7.2 electricity generation

Hydro

ref e[r] adv

Biomass

ref e[r] adv

Wind

ref e[r] adv

geotHermal

ref e[r] adv

a 100% electricity supply from renewable energy resources in the advanced scenario leads to around 1,790 gW installed generation capacity in 2050.

ref e[r] adv

csP

ref e[r]

table 6.7.1 shows the comparative evolution of the different renewable technologies in eastern europe/eurasia over time. Up to 2020 wind, biomass and Pv will become the main contributors to the growing market share. after 2020, the continuing growth of wind, biomass and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. the energy [r]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 23% to 29% by 2030 and 52% to 61% by 2050. therefore, smart grids, demand side management (dsm), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

adv ocean

ref e[r] adv

total

ref e[r] adv

2012 93 93 93 1 1 1 4 4 4 0 0 0 1 1 1 0 0 0 0 0 0 99 99 99

2020 103 103 103 3 16 16 8 18 19 0 1 1 4 7 7 0 0 0 0 0 0 119 145 145

2030 114 111 111 5 39 39 13 187 252 1 8 13 6 107 157 0 1 2 0 2 3 139 457 578

2040 125 114 114 9 67 67 20 370 542 2 26 44 7 246 399 0 5 10 0 11 16 164 839 1,190

2050 139 115 115 13 90 91 27 506 869 3 40 81 9 342 600 0 8 12 0 18 25 191 1,119 1,793

figure 6.7.5 | eastern europe/eurasia: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 6,000 OCEAN ENERGY

5,000

CSP GEOTHERMAL BIOMASS

4,000

TWh/a

table 6.7.1 | eastern europe/eurasia: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios in gw

the development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. this trend will more than compensate for the phasing out of nuclear power production in the energy [r]evolution scenarios, continuously reducing the number of fossil fuelfired power plants as well. By 2050, 86% of the electricity produced in eastern europe/eurasia will come from renewable energy sources in the basic energy [r]evolution scenario. ‘new’ renewables – mainly wind, Pv, csP and geothermal energy – will contribute 51% to the total electricity generation. already by 2020 the share of renewable electricity production will be 23% and 49% by 2030. the installed capacity of renewables will reach about 460 gW in 2030 and 1,120 gW by 2050.

WIND

3,000

HYDRO HYDROGEN NUCLEAR

2,000

DIESEL OIL

1,000

GAS LIGNITE COAL

146

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.7.3 future costs of electricity generation

6.7.4 future investments in the power sector

figure 6.7.6 shows that the introduction of renewable technologies under both energy [r]evolution scenarios increases the future costs of electricity generation compared to the reference scenario until 2020. this difference in full cost of generation will be less than 0.2 Us$ct/kWh in both energy [r]evolution scenarios, without taking into account integration costs for storage or other load-balancing measures. Because of increasing prices for conventional fuels, electricity generation costs will become economically favourable before 2030 under the energy [r]evolution scenarios. By 2050, the cost in the basic energy [r]evolution scenario will be 2.2 Us$ct/kWh below those in the reference case, in the advanced scenario the cost will be equal to the reference case.

around Us$ 2,970 billion is required in investment for the energy [r]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 76 billion per year, Us$ 1,690 billion more than in the reference scenario (Us$ 1,280 billion). investments for the advanced scenario add up to Us$ 4,390 billion until 2050, on average Us$ 113 billion per year, including high investments in additional power plants for the production of synthetic fuels. Under the reference scenario, the levels of investment in conventional power plants add up to almost 41% while approximately 59% would be invested in renewable energies and cogeneration until 2050.

Under the energy [r]evolution scenarios, however, eastern europe/eurasia would shift almost 97% of the entire investment towards renewables and cogeneration. By 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants.

increasing energy efficiency and shifting energy supply to renewables lead to long term costs for electricity supply that are 14% lower in the basic energy [r]evolution scenario than in the reference scenario despite a 5% increase in electricity production. the advanced scenario with 100% renewable power and an increase in power generation of 58% results in supply costs 49% higher than the reference case.

Because renewable energy has no fuel costs, the fuel cost savings in the basic energy [r]evolution scenario reach a total of Us$ 3,280 billion up to 2050, Us$ 84 billion per year. the total fuel cost savings therefore would cover 190% of the total additional investments compared to the reference scenario. fuel cost savings in the advanced scenario are even higher and add up to Us$ 3,540 billion, or Us$ 91 billion per year. renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.7.6 | eastern europe/eurasia: development of total electricity supply costs & of specific electricity generation costs in the scenarios

figure 6.7.7 | eastern europe/eurasia: investment shares - reference versus energy [r]evolution scenarios

Billion $

US$ct/kWh

700

FOSSIL,

600

ref 2012-2050

TOTAL

1,280 BILLION USD

500

CHP,

300

e[r] 2012-2050

TOTAL

2,970 BILLION RENEWABLE,

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

28%

USD

100

17%

25%

FOSSIL,

NUCLEAR, CHP,

400

200

24% 34%

RENEWABLE,

FOSSIL, CHP,

adv e[r] 2012-2050

69%

20%

TOTAL

4,400 BILLION USD

RENEWABLE,

77%

147

world energy [r]evolution a sustainable world energy outlook

6.7.5 energy supply for heating

Biomass

ref e[r] adv

solar Heating

ref e[r] adv

• energy efficiency measures help to reduce the currently growing energy demand for heating by 44% in 2050 (relative to the reference scenario), in spite of improving living standards and economic growth.

geotHermal Heat ref and Heat PUmPs

e[r] adv

Hydrogen

ref e[r]

adv ref

total

e[r] adv

2012 509 509 509 4 4 4 6 6 6 0 0 0 519 519 519

2020 904 2,188 2,188 7 361 361 8 343 343 0 0 44 918 2,891 2,935

2030 995 2,850 2,850 8 840 840 9 922 922 0 0 162 1,012 4,611 4,775

2040 1,190 4,047 4,042 10 2,014 2,014 12 2,741 2,863 0 146 692 1,213 8,949 9,609

2050 1,421 4,365 4,360 14 2,271 2,273 15 3,794 4,332 0 442 1,492 1,449 10,872 12,457

• a shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of co 2 emissions. table 6.7.2 shows the development of different renewable technologies for heating in eastern europe/eurasia over time. Up to 2030 biomass remains the main contributor of the growing market share. after 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will further reduce the dependence on fossil fuels. the advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.7.8 | eastern europe/eurasia: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 30,000

25,000

20,000

PJ/a

table 6.7.2 | eastern europe/eurasia: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in pj /a

today, renewables meet around 4% of eastern europe/eurasia’s energy demand for heating, the main contribution coming from the use of biomass. dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. in the basic energy [r]evolution scenario, renewables already provide 29% of eastern europe/eurasia’s total heat demand in 2030 and 86% in 2050.

15,000 EFFICIENCY HYDROGEN

10,000

ELECTRIC HEATING GEOTHERMAL HEATING

& HEAT PUMPS

5,000

SOLAR HEATING BIOMASS FOSSIL

148

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.7.6 future investments in the heating sector

also in the heating sector the energy [r]evolution scenarios would require a major revision of current investment strategies in heating technologies. in particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. the use of biomass for heating purposes - often traditional biomass today - will be substantially reduced in the energy [r]evolution scenarios and replaced by more efficient and sustainable renewable heating technologies. renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. thus, it can only be roughly estimated that the energy [r]evolution scenario in total requires around Us$ 1,790 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) approximately Us$ 46 billion per year. the advanced scenario assumes an even more ambitious expansion of renewable technologies resulting in an average investment of around Us$ 48 billion per year, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with hydrogen or other synthetic fuels.

table 6.7.3 | eastern europe/eurasia: installed capacities for renewable heat generation under the scenarios in gw

Biomass

ref e[r] adv

geotHermal

ref e[r] adv

solar Heating

ref e[r] adv

Heat PUmPs

ref e[r] adv

total*

ref e[r] adv

2012 108 108 108 0 0 0 1 1 1 1 1 1 110 110 110

2020 171 224 224 0 1 1 1 14 14 1 8 8 174 247 247

2030 195 349 349 0 49 49 2 182 182 2 76 76 198 655 655

2040 220 412 411 0 151 151 3 445 445 2 213 232 224 1,221 1,238

2050 248 385 380 0 193 197 3 503 506 3 276 321 254 1,357 1,404

* excluding direct electric heating.

figure 6.7.9 | eastern europe/eurasia: development of investments for renewable heat generation technologies â&#x20AC;&#x201C; reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050

e[r] 2012-2050

SOLAR, 1% HEAT PUMPS,

adv e[r] 2012-2050

BIOMASS,

22%

HEAT PUMPS,

32%

TOTAL

1,790 BILLION USD

250 BILLION USD

BIOMASS,

97%

BIOMASS,

20%

HEAT PUMPS,

35%

TOTAL

GEOTHERMAL,

SOLAR,

25%

21%

1,850 BILLION USD

GEOTHERMAL,

SOLAR,

21%

24%

149

world energy [r]evolution a sustainable world energy outlook

6.7.7 future employment in the energy sector

the advanced Energy [R]evolution scenario results in more energy sector jobs in Eastern Europe/Eurasia at every stage of the projection.

figure 6.7.10 | eastern europe/eurasia: employment in the energy sector under the reference and advanced energy [r]evolution scenario

• there are 1.8 million energy sector jobs in the advanced energy [r]evolution in 2020, and 1.6 million in the reference scenario.

• in 2030, there are 2.9 million jobs in the advanced energy [r]evolution scenario and 1.5 million in the reference scenario. figure 6.7.10 shows the change in job numbers under both scenarios for each technology between 2015 and 2030. Jobs in the reference scenario reduce gradually over the period, leading to an overall decline of 10% by 2030.

3.0

Direct jobs - Millions

• in 2025, there are 2.7 million jobs in the advanced energy [r]evolution scenario, and 1.5 million in the reference scenario.

3.5

strong growth in renewable energy leads to an increase of 10% in total energy sector jobs in the advanced energy [r]evolution scenario by 2020, compensating for a strong decline in coal. Jobs continue to grow until 2030, reaching 72% above 2015 levels. renewable energy accounts for 70% of energy jobs by 2030, with biomass having the greatest share (18%).

2.5 2.0 1.5 1.0 0.5 0

2015

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

& HEAT PUMP

- HEAT

2025

2030

ADVANCED E[R] WIND HYDRO

OCEAN

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

table 6.7.4 | eastern europe/eurasia: total employment in the energy sector

& DIESEL

in thousand jobs

advanced energy [r]evolution

reference

2015

2020

2025

2030

2020

2025

2030

738 669 82 186 1,675

568 728 91 199 1,587

449 789 80 206 1,525

390 841 66 205 1,502

346 707 56 740 1,849

167 728 56 1,705 2,655

52 773 54 2,006 2,886

70 26 252 1,028 299 1,675

84 32 267 817 386 1,587

67 30 270 732 426 1,525

65 33 254 685 465 1,502

308 134 321 844 243 1,849

783 399 443 780 251 2,655

866 451 562 707 299 2,886

jobs by fuel

coal gas, oil

diesel

nuclear renewables total jobs jobs by sector

construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs

150

energy

[r]evolution

6.7.8 transport table 6.7.5 | eastern europe/eurasia: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in pj /a

a key target in eastern europe/eurasia is to introduce incentives for people to drive smaller cars and buy new, more efficient vehicle concepts. in addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the metropolitan areas. along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the reference scenario. due to population increase, gdP growth and higher living standards, energy demand from the transport sector is expected to increase in the reference scenario by around 38% to 8,310 PJ/a in 2050. in the basic energy [r]evolution scenario, efficiency measures and modal shifts will save 49% (4,060 PJ/a) in 2050 compared to the reference scenario.

rail

ref e[r] adv

road

ref e[r] adv

domestic aviation ref e[r] adv

additional modal shifts and technology switches lead to even higher energy savings in the advanced scenario of 59% (4,880 PJ/a) in 2050 compared to the reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. By 2030, electricity will provide 13% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the energy [r]evolution, while in 2050 the share will be 51% (61% in the advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. in 2050, up to 460 PJ/a of hydrogen is used in the transport sector for the advanced energy [r]evolution scenario.

domestic

ref

navigation

e[r] adv ref

total

e[r] adv

2012 591 591 591 3,712 3,712 3,712 297 297 297 45 45 45 4,646 4,646 4,646

2020 658 639 639 4,450 4,013 4,013 360 337 337 68 66 66 5,536 5,055 5,055

2030 682 685 749 4,846 4,151 3,859 382 347 330 71 65 65 5,981 5,248 5,004

2040 732 740 910 5,404 3,729 3,040 429 357 311 72 61 61 6,636 4,888 4,322

2050 777 780 985 5,515 2,648 1,990 474 365 292 75 57 57 6,841 3,850 3,324

figure 6.7.11 | eastern europe/eurasia: final energy consumption in transport under the scenarios

9,000 8,000 7,000

PJ/a

6,000 5,000 4,000

EFFICIENCY HYDROGEN

3,000

ELECTRICITY

2,000

SYNFUELS BIOFUELS

1,000

NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

151

world energy [r]evolution a sustainable world energy outlook

6.7.10 development of co 2 emissions

CO2 emissions [Mt/a]

With a 39% share of co 2, the Power generation sector will be the largest source of emissions in 2050 in the basic energy [r]evolution scenario. By 2050, eastern europe/eurasia´s co 2 emissions are around 92% below 1990 levels in the energy [r]evolution scenario while energy consumption is fully decarbonised in the advanced case.

population (million)

4,000

400

3,500

350

3,000

300

2,500

250

2,000

200

1,500

150

1,000

100 50

500 0

6.7.11 primary energy consumption

taking into account the assumptions discussed above, the resulting primary energy consumption under the energy [r]evolution scenarios is shown in figure 6.7.12. Under the basic energy [r]evolution scenario, primary energy demand will decrease by 29% from today’s 49,310 PJ/a to around 35,000 PJ/a. compared to the reference scenario, overall primary energy demand will be reduced by 47% in 2050 under the energy [r]evolution scenario (reference scenario: around 66,000 PJ in 2050). the advanced scenario results due to additional conversion losses in a primary energy consumption of around 39,700 PJ in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

renewable energies and a fast introduction of very efficient vehicle concepts in the transport sector to replace oil based combustion engines. this leads to an overall renewable primary energy share of 25% in 2030 and 73% in 2050 in the basic energy [r]evolution and of more than 91% in 2050 in the advanced case (incl. non-energy consumption). in contrast to the reference scenario, no new nuclear power plants will be built in eastern europe/eurasia in the energy [r]evolution scenarios.

the energy [r]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by expansion of

figure 6.7.12 | eastern europe/eurasia: projection of total primary energy demand (ped) by energy carrier including electricity including electricity import balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 70,000

60,000 EFFICIENCY

50,000

OCEAN ENERGY GEOTHERMAL

40,000

SOLAR

PJ/a

figure 6.7.13 | eastern europe/eurasia: development of co2 emissions by sector under the energy [r]evolution scenarios ‘savings ’ = reduction compared to the reference scenario

Whilst eastern europe/eurasia’s emissions of co 2 will increase by 31% between 2012 and 2050 under the reference scenario, under the energy [r]evolution scenario they will decrease from 2,710 million tonnes in 2012 to 317 million tonnes in 2050. annual per capita emissions will drop from 8 tonne to 1 tonne. in spite of the abstinence of nuclear power production and increasing power demand, co 2 emissions will decrease in the electricity sector. in the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well.

BIOMASS

30,000

WIND

20,000

NATURAL GAS

HYDRO

CRUDE OIL COAL

10,000

NUCLEAR NET ELECTRICITY IMPORTS

152

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.7.6 | eastern europe/eurasia: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

36.0 -37.4 -1.4

112.7 -504.1 -391.3

85.3 -715.3 -630.0

166.3 -857.1 -690.8

400.3 -2,113.9 -1,713.6

10.3 -54.2 -43.9

$ $ $ $ $ $

3.4 -4.5 7.5 3.0 3.5 12.8

21.4 219.7 78.6 23.1 36.5 379.2

13.8 750.9 180.6 43.0 86.9 1,075.3

3.0 1,380.3 256.4 51.5 122.3 1,813.6

41.5 2,346.4 523.2 120.6 249.1 3,280.9

1.1 60.2 13.4 3.1 6.4 84.1

average per year nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.7.7 | eastern europe/eurasia: accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

58.3

320.6

666.1

495.1

1,540.1

2012 - 2050 average per year

39.5

table 6.7.8 | eastern europe/eurasia: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs advanced e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

33.1 -37.9 -4.9

116.2 -756.3 -640.1

54.2 -1,133.2 -1,079.0

163.0 -1,572.4 -1,409.4

366.4 -3,499.8 -3,133.4

9.4 -89.7 -80.3

$ $ $ $ $ $

3.4 -4.5 7.5 3.0 3.5 12.9

21.4 228.7 83.0 23.1 36.5 392.6

13.8 799.4 189.6 43.0 86.9 1,132.7

3.0 1,568.3 257.5 51.5 122.3 2,002.7

41.5 2,591.9 537.7 120.6 249.1 3,540.9

1.1 66.5 13.8 3.1 6.4 90.8

average per year

nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative advanced e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.7.9 | eastern europe/eurasia: accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs advanced e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

58.3

320.6

695.1

528.7

1,602.7

2012 - 2050 average per year

41.1

153

world energy [r]evolution a sustainable world energy outlook

6.8 india this reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. the transformation to a carbon free energy system in the advanced scenario will further increase the electricity demand in 2050 up to 5,500 tWh/a. electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. around 1,190 tWh are used in 2050 for electric vehicles and rail transport in 2050 in the advanced scenario, around 440 tWh for hydrogen and 540 tWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.8.1 final energy demand by sector

efficiency gains in the heating sector are even larger than in the electricity sector. Under the energy [r]evolution scenarios, consumption equivalent to about 6,200 PJ/a is avoided through efficiency gains by 2050 compared to the reference scenario. as a result of energy-related renovation of the existing stock of residential buildings, the introduction of low energy standards and ‘passive climatisation’ for new buildings, as well as highly efficient air conditioning systems, enjoyment of the same comfort and energy services will be accompanied with much lower future energy demand.

Under both energy [r]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.8.2). total electricity demand will decrease from about 870 tWh/a to 4,920 tWh/a by 2050 in the basic energy [r]evolution scenario. compared to the reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 1,080 tWh/a.

figure 6.8.1 | india: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat from chp autoproducers 70,000

60,000

50,000

40,000 PJ/a

combining the projections on population development, gdP growth and energy intensity results in future development pathways for india’s final energy demand. these are shown in figure 6.8.1 for the reference and energy [r]evolution scenarios. Under the reference scenario, total final energy demand increases by 208% from the current 19,900 PJ/a to 61,200 PJ/a in 2050. in the basic energy [r]evolution scenario, final energy demand increases at a much lower rate by 79% compared to current consumption and is expected to reach 35,600 PJ/a by 2050. the advanced scenario results in some additional reductions due to a higher share of electric cars.

30,000

20,000 EFFICIENCY OTHER SECTORS

10,000

INDUSTRY TRANSPORT

154

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.8.2 | india: development of electricity demand by sector in the energy [r]evolution scenarios

figure 6.8.4 | india: development of final energy demand for heat by sector in the energy [r]evolution scenarios 30,000

25,000

20,000

20,000 PJ/a

PJ/a

15,000

10,000

15,000

10,000

5,000

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.8.3 | india: development of the final energy demand for transport by sector in the energy [r]evolution scenarios 20,000 18,000 16,000 14,000

PJ/a

12,000 10,000 8,000 6,000 4,000 4,000 0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

155

world energy [r]evolution a sustainable world energy outlook

6.8.2 electricity generation

Hydro

ref e[r] adv

Biomass

ref e[r] adv

Wind

ref e[r] adv

geotHermal

ref e[r] adv

a 100% electricity supply from renewable energy resources in the advanced scenario leads to around 3,260 gW installed generation capacity in 2050.

ref e[r] adv

csP

table 6.8.1 shows the comparative evolution of the different renewable technologies in india over time. Up to 2020 wind and Pv will become the main contributors to the growing market share. after 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. the energy [r]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 38% to 47% by 2030 and 62% to 70% by 2050. therefore, smart grids, demand side management (dsm), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

ref e[r] adv

ocean

ref e[r] adv

total

ref e[r] adv

2012 42 42 42 6 6 6 18 18 18 0 0 0 1 1 1 0 0 0 0 0 0 68 68 68

2020 54 54 54 9 14 14 34 43 46 0 0 0 15 64 68 0 1 1 0 0 0 112 176 183

2030 76 66 66 12 30 29 50 320 449 0 7 8 35 302 390 0 40 46 0 10 11 173 775 999

2040 101 68 68 15 51 54 62 667 1,048 0 36 43 47 576 828 0 125 146 0 28 31 226 1,551 2,218

2050 126 69 69 19 79 87 72 941 1,518 0 64 73 59 841 1,222 0 194 234 0 52 59 277 2,240 3,263

figure 6.8.5 | india: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 9,000 8,000

OCEAN ENERGY CSP

7,000

GEOTHERMAL BIOMASS

6,000

TWh/a

table 6.8.1 | india: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios in gw

the development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. this trend will more than compensate for the phasing out of nuclear power production in the energy [r]evolution scenarios, continuously reducing the number of fossil fuelfired power plants as well. By 2050, 93% of the electricity produced in india will come from renewable energy sources in the basic energy [r]evolution scenario. ‘new’ renewables – mainly wind, Pv, csP and geothermal energy – will contribute 71% to the total electricity generation. already by 2020 the share of renewable electricity production will be 23% and 56% by 2030. the installed capacity of renewables will reach about 770 gW in 2030 and 2,240 gW by 2050.

5,000

WIND HYDRO

4,000

HYDROGEN NUCLEAR

3,000

DIESEL

2,000

OIL GAS

1,000

LIGNITE COAL

156

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.8.3 future costs of electricity generation

6.8.4 future investments in the power sector

figure 6.8.6 shows that the introduction of renewable technologies under both energy [r]evolution scenarios increases the future costs of electricity generation compared to the reference scenario until 2030. this difference in full cost of generation will be about 0.1 Us$ct/kWh in the advanced scenario, without taking into account integration costs for storage or other load-balancing measures. Because of increasing prices for conventional fuels, electricity generation costs will become economically favourable starting in 2030 under the energy [r]evolution scenarios. By 2050, the cost will be 2.1/1.6 Us$ct/kWh, respectively, below those in the reference case.

around Us$ 5,370 billion is required in investment for the energy [r]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 138 billion per year, Us$ 3,110 billion more than in the reference scenario (Us$ 2,260 billion). investments for the advanced scenario add up to Us$ 7,220 billion until 2050, on average Us$ 185 billion per year, including high investments in additional power plants for the production of synthetic fuels. Under the reference scenario, the levels of investment in conventional power plants add up to almost 72% while approximately 28% would be invested in renewable energies and cogeneration until 2050.

Under the energy [r]evolution scenarios, however, india would shift up to 95% of the entire investment towards renewables and cogeneration. By 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants.

increasing energy efficiency and shifting energy supply to renewables lead to long term costs for electricity supply that are 3% higher than in the basic energy [r]evolution scenario than in the reference scenario, despite a 19% increase in electricity production. the advanced scenario with 100% renewable power and an increase in power generation of 60% results in supply costs 43% higher than the reference case.

figure 6.8.6 | india: development of total electricity supply costs & of specific electricity generation costs in the scenarios Billion $

Because renewable energy has no fuel costs, the fuel cost savings in the basic energy [r]evolution scenario reach a total of Us$ 3,430 billion up to 2050, Us$ 88 billion per year. the total fuel cost savings therefore would cover 110% of the total additional investments compared to the reference scenario. fuel cost savings in the advanced scenario are even higher and add up to Us$ 3,720 billion, or Us$ 95 billion per year. renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.8.7 | india: investment shares - reference versus energy [r]evolution scenarios

US$ct/kWh

800

FOSSIL,

10 9

700

600

ref 2012-2050

TOTAL

2,260 BILLION USD

500

65% 28%

RENEWABLE,

NUCLEAR,

400

FOSSIL,

CHP,

300

200

e[r] 2012-2050

100

TOTAL

5,370 BILLION

6% 7%

RENEWABLE,

87%

USD

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

FOSSIL, 5% CHP, 5%

adv e[r] 2012-2050

TOTAL

7,220 BILLION

RENEWABLE,

90%

USD

157

world energy [r]evolution a sustainable world energy outlook

6.8.5 energy supply for heating table 6.8.2 | india: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in pj /a

today, renewables meet around 50% of india’s energy demand for heat, the main contribution coming from the use of biomass. dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. in the basic energy [r]evolution scenario, renewables already provide 55% of india’s total heat demand in 2030 and 87% in 2050.

ref e[r] adv

solar Heating

ref e[r]

• energy efficiency measures help to reduce the currently growing energy demand for heating by 25% in 2050 (relative to the reference scenario), in spite of improving living standards and economic growth.

adv geotHermal Heat ref and Heat PUmPs

e[r] adv

Hydrogen

ref e[r] adv ref

total

e[r] adv

2012 5,433 5,433 5,433 20 20 20 0 0 0 0 0 0 5,453 5,453 5,453

2020 6,042 5,955 5,955 80 522 521 1 175 175 0 0 6 6,123 6,653 6,658

2030 6,219 5,905 5,905 106 1,175 1,175 1 641 641 0 8 36 6,326 7,731 7,756

2040 6,223 5,680 5,680 171 2,391 2,392 1 1,678 1,722 0 164 338 6,396 9,913 10,133

2050 6,334 5,320 5,320 261 3,320 3,436 2 2,940 3,182 0 614 1,546 6,597 12,194 13,483

• a shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of co 2 emissions. table 6.8.2 shows the development of different renewable technologies for heating in india over time. Up to 2030 biomass remains the main contributor of the growing market share. after 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will further reduce the dependence on fossil fuels. the advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.8.8 | india: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 30,000

25,000

20,000

PJ/a

Biomass

15,000 EFFICIENCY HYDROGEN

10,000

ELECTRIC HEATING GEOTHERMAL HEATING

& HEAT PUMPS

5,000

SOLAR HEATING BIOMASS FOSSIL

158

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.8.6 future investments in the heating sector

also in the heating sector the energy [r]evolution scenarios would require a major revision of current investment strategies in heating technologies. in particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. the use of biomass for heating purposes - often traditional biomass today - will be substantially reduced in the energy [r]evolution scenarios and replaced by more efficient and sustainable renewable heating technologies. renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. thus, it can only be roughly estimated that the energy [r]evolution scenario in total requires around Us$ 1,020 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) approximately Us$ 26 billion per year. the advanced scenario assumes an even more ambitious expansion of renewable technologies resulting in an average investment of around Us$ 27 billion per year, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with hydrogen or other synthetic fuels.

table 6.8.3 | india: installed capacities for renewable heat generation under the scenarios in gw

Biomass

ref e[r] adv

geotHermal

ref e[r] adv

solar Heating

ref e[r] adv

Heat PUmPs

ref e[r] adv

total*

ref e[r] adv

2012 2,200 2,200 2,200 0 0 0 5 5 5 0 0 0 2,205 2,205 2,205

2020 2,290 2,240 2,240 0 0 0 13 19 19 0 1 1 2,303 2,260 2,260

2030 2,240 2,050 2,050 0 13 13 25 270 270 0 37 37 2,265 2,370 2,370

2040 2,040 1,690 1,690 0 38 42 40 540 540 0 80 80 2,080 2,348 2,352

2050 1,860 1,270 1,270 0 82 101 60 730 750 0 130 130 1,921 2,212 2,251

* excluding direct electric heating.

figure 6.8.9 | india: development of investments for renewable heat generation technologies â&#x20AC;&#x201C; reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050 SOLAR,

e[r] 2012-2050

adv e[r] 2012-2050

BIOMASS,

14%

HEAT PUMPS, TOTAL

TOTAL

333 BILLION USD

1,020 BILLION USD

BIOMASS,

93%

GEOTHERMAL,

SOLAR,

42%

BIOMASS,

27% 17%

13%

HEAT PUMPS, TOTAL

1,060 BILLION USD

GEOTHERMAL,

SOLAR,

25% 20%

42%

159

world energy [r]evolution a sustainable world energy outlook

6.8.7 future employment in the energy sector

the advanced Energy [R]evolution scenario results in more energy sector jobs in India at every stage of the projection.

figure 6.8.10 | india: employment in the energy sector under the reference and advanced energy [r]evolution scenario

• there are 6.3 million energy sector jobs in the advanced energy [r]evolution in 2020, and 5.3 million in the reference scenario.

• in 2030, there are 8.6 million jobs in the advanced energy [r]evolution scenario and 4.2 million in the reference scenario. figure 6.8.10 shows the change in job numbers under both scenarios for each technology between 2015 and 2030. Jobs in the reference scenario increase by 17% by 2020, before declining to 7% below 2015 levels in 2030.

9.0 8.0 Direct jobs - Millions

• in 2025, there are 8.9 million jobs in the advanced energy [r]evolution scenario, and 5 million in the reference scenario.

10.0

exceptionally strong growth in renewable energy offsets losses in the fossil fuel sector. advanced energy [r]evolution jobs increase to 38% above 2015 levels in 2020 and are nearly double 2015 levels in 2025. jobs reduce sligthly from 2025 to 2030, but remain 89% above 2015 levels. renewable energy accounts for 91% of energy jobs in 2030, with wind having the greatest share (31%), followed by solar pV, and biomass.

table 6.8.4 | india: total employment in the energy sector

7.0 6.0 5.0 4.0 3.0 2.0 1.0 0

2015

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

& HEAT PUMP

- HEAT

2025

2030

ADV E[R] WIND HYDRO

OCEAN

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

& DIESEL

in thousand jobs

advanced energy [r]evolution

reference

2015

2020

2025

2030

2020

2025

2030

2,252 203 84 1,993 4,533

2,769 252 118 2,158 5,297

2,552 298 133 1,989 4,972

2,324 278 120 1,483 4,205

839 301 31 5,095 6,266

618 410 26 7,889 8,942

384 333 18 7,817 8,553

1,241 633 414 2,244 4,533

1,637 824 560 2,276 5,297

1,445 725 654 2,148 4,972

1,221 603 621 1,761 4,205

1,496 1,704 780 2,286 6,266

2,866 2,759 1,239 2,079 8,942

2,799 2,612 1,625 1,516 8,553

jobs by fuel

coal gas, oil

diesel

nuclear renewables total jobs jobs by sector

construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs

160

energy

[r]evolution

6.8.8 transport table 6.8.5 | india: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in pj /a

in 2050, the car fleet in india will be significantly larger than today. therefore a key target is the successful introduction of highly efficient vehicle concepts. in addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the expanding large metropolitan areas. along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the reference scenario. due to population increase, gdP growth and higher living standards, energy demand from the transport sector is expected to strongly increase in the reference scenario by around 518% to 19,030 PJ/a in 2050. in the basic energy [r]evolution scenario, efficiency measures and modal shifts will save 50% (9,530 PJ/a) in 2050 compared to the reference scenario.

rail

ref e[r] adv

road

ref e[r] adv

domestic aviation ref e[r] adv domestic

ref

navigation

e[r] adv

additional modal shifts and technology switches lead to even higher energy savings in the advanced scenario of 64% (12,100 PJ/a) in 2050 compared to the reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. By 2030, electricity will provide 5% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the energy [r]evolution, while in 2050 the share will be 38% (62% in the advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. in 2050, up to 1,220 PJ/a of hydrogen is used in the transport sector for the advanced energy [r]evolution scenario.

ref

total

e[r] adv

2012 168 168 168 2,811 2,811 2,811 71 71 71 29 29 29 3,078 3,078 3,078

2020 261 228 234 6,326 4,390 4,356 175 132 131 72 57 57 6,834 4,807 4,779

2030 297 314 450 8,147 7,093 6,458 227 216 201 92 87 87 8,762 7,711 7,196

2040 356 390 894 13,031 8,209 5,849 379 322 251 132 112 112 13,898 9,034 7,107

2050 387 450 1,342 17,844 8,477 5,196 632 442 265 170 130 130 19,033 9,500 6,934

figure 6.8.11 | india: final energy consumption in transport under the scenarios

20,000 18,000 16,000 14,000

PJ/a

12,000 10,000 EFFICIENCY

8,000

HYDROGEN

6,000

ELECTRICITY SYNFUELS

4,000

BIOFUELS

2,000

NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

161

world energy [r]evolution a sustainable world energy outlook

6.8.10 development of co 2 emissions

CO2 emissions [Mt/a]

population (million)

8,000

1,800

7,000

1,600 1,400

6,000

1,200

5,000

With a 34% share of co 2, the transport sector will be the largest source of emissions in 2050 in the basic energy [r]evolution scenario. By 2050, india´s co 2 emissions are still 34% above 1990 levels in the energy [r]evolution scenario while energy consumption is fully decarbonised in the advanced case.

1,000

4,000

800

3,000

600

2,000

400

1,000

200

6.8.11 primary energy consumption

taking into account the assumptions discussed above, the resulting primary energy consumption under the energy [r]evolution scenarios is shown in figure 6.8.12. Under the basic energy [r]evolution scenario, primary energy demand will increase by 58% from today’s 32,940 PJ/a to around 52,000 PJ/a. compared to the reference scenario, overall primary energy demand will be reduced by 47% in 2050 under the energy [r]evolution scenario (reference scenario: around 99,000 PJ in 2050). the advanced scenario results in a primary energy consumption of around 51,300 PJ in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

replace oil based combustion engines. this leads to an overall renewable primary energy share of 34% in 2030 and 74% in 2050 in the basic energy [r]evolution and of more than 94% in 2050 in the advanced case (incl. non-energy consumption). in contrast to the reference scenario, no new nuclear power plants will be built in india in the energy [r]evolution scenarios.

the energy [r]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by expansion of renewable energies and a fast introduction of very efficient vehicle concepts in the transport sector to

figure 6.8.12 | india: projection of total primary energy demand (ped) by energy carrier including electricity import balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 100,000

80,000

NET ELECTRICITY IMPORTS EFFICIENCY OCEAN ENERGY

60,000

GEOTHERMAL

PJ/a

figure 6.8.13 | india: development of co 2 emissions by sector under the energy [r]evolution scenarios ‘ savings ’ = reduction compared to the reference scenario

Whilst india’s emissions of co 2 will increase by 248% between 2012 and 2050 under the reference scenario, under the energy [r]evolution scenario they will decrease from 1,950 million tonnes in 2012 to 780 million tonnes in 2050. annual per capita emissions will drop from 1.6 tonne to 0.5 tonne. in spite of the abstinence of nuclear power production and increasing power demand, co 2 emissions will decrease in the electricity sector. in the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well.

SOLAR BIOMASS

40,000

WIND HYDRO NATURAL GAS

20,000

CRUDE OIL COAL NUCLEAR

162

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.8.6 | india: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

44.5 -114.7 -70.2

363.8 -1,010.7 -646.9

438.4 -1,504.5 -1,066.1

423.9 -1,764.5 -1,340.6

1,270.5 -4,394.3 -3,123.8

32.6 -112.7 -80.1

$ $ $ $ $ $

2.9 -5.3 15.5 0.9 0.5 14.6

17.8 -33.0 322.5 15.7 8.9 331.9

31.8 150.7 874.0 58.4 27.0 1,142.0

20.5 386.1 1,354.0 124.3 54.3 1,939.1

73.0 498.6 2,566.1 199.2 90.7 3,427.6

1.9 12.8 65.8 5.1 2.3 87.9

average per year nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.8.7 | india: accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

-61.4

161.2

224.8

360.1

684.7

2012 - 2050 average per year

17.6

table 6.8.8 | india: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs advanced e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

44.8 -130.9 -86.2

365.7 -1,377.2 -1,011.5

437.9 -2,179.3 -1,741.4

406.5 -2,545.9 -2,139.5

1,254.8 -6,233.3 -4,978.5

32.2 -159.8 -127.7

$ $ $ $ $ $

2.9 -5.3 15.7 0.9 0.5 14.7

17.8 -30.6 346.2 15.7 8.9 357.9

31.8 167.7 961.6 58.4 27.0 1,246.4

20.5 485.6 1,416.0 124.3 54.3 2,100.6

73.0 617.3 2,739.5 199.2 90.7 3,719.7

1.9 15.8 70.2 5.1 2.3 95.4

average per year

nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative advanced e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.8.9 | india: accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs advanced e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

-61.4

160.6

231.7

396.1

727.0

2012 - 2050 average per year

18.6

163

world energy [r]evolution a sustainable world energy outlook

6.9 other asia this reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. the transformation to a carbon free energy system in the advanced scenario will further increase the electricity demand in 2050 up to 4,000 tWh/a. electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. around 680 tWh are used in 2050 for electric vehicles and rail transport in 2050 in the advanced scenario, around 630 tWh for hydrogen and 70 tWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.9.1 final energy demand by sector

efficiency gains in the heating sector are even larger than in the electricity sector. Under the energy [r]evolution scenarios, consumption equivalent to about 6,100 PJ/a is avoided through efficiency gains by 2050 compared to the reference scenario. as a result of energy-related renovation of the existing stock of residential buildings, the introduction of low energy standards and ‘passive climatisation’ for new buildings, as well as highly efficient air conditioning systems, enjoyment of the same comfort and energy services will be accompanied with much lower future energy demand.

Under both energy [r]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.9.2). total electricity demand will rise from about 1,080 tWh/a to 3,680 tWh/a by 2050 in the basic energy [r]evolution scenario. compared to the reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 1,730 tWh/a.

figure 6.9.1 | other asia: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat from chp autoproducers 60,000

50,000

40,000

PJ/a

combining the projections on population development, gdP growth and energy intensity results in future development pathways for other asia’s final energy demand. these are shown in figure 6.9.1 for the reference and energy [r]evolution scenarios. Under the reference scenario, total final energy demand increases by 118% from the current 23,000 PJ/a to 50,200 PJ/a in 2050. in the basic energy [r]evolution scenario, final energy demand increases at a much lower rate by 25% compared to current consumption and is expected to reach 28,800 PJ/a by 2050. the advanced scenario results in some additional reductions due to a higher share of electric cars.

30,000

20,000 EFFICIENCY

10,000

OTHER SECTORS INDUSTRY TRANSPORT

164

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.9.4 | other asia: development of final energy demand for heat by sector in the energy [r]evolution scenarios

figure 6.9.2 | other asia: development of electricity demand by sector in the energy [r]evolution scenarios

25,000

16,000

14,000 20,000

12,000

15,000 PJ/a

PJ/a

10,000 8,000

10,000

6,000 4,000

5,000

2,000 0

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.9.3 | other asia: development of the final energy demand for transport by sector in the energy [r]evolution scenarios 14,000 12,000 10,000

PJ/a

8,000 6,000 4,000 2,000 0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

165

world energy [r]evolution a sustainable world energy outlook

6.9.2 electricity generation

Hydro

ref e[r] adv

Biomass

ref e[r] adv

Wind

ref e[r] adv

geotHermal

ref e[r] adv

a 100% electricity supply from renewable energy resources in the advanced scenario leads to around 2,450 gW installed generation capacity in 2050.

ref e[r] adv

csP

table 6.9.1 shows the comparative evolution of the different renewable technologies in other asia over time. Up to 2020 wind and Pv will become the main contributors to the growing market share. after 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. the energy [r]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 33% to 34% by 2030 and 57% to 54% by 2050. therefore, smart grids, demand side management (dsm), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

ref e[r] adv

ocean

ref e[r] adv

total

ref e[r] adv

2012 52 52 52 5 5 5 1 1 1 3 3 3 1 1 1 0 0 0 0 0 0 62 62 62

2020 74 75 75 10 11 11 5 33 33 4 5 5 6 36 36 0 0 0 0 0 0 99 161 161

2030 107 85 86 14 16 17 16 196 201 6 32 36 15 235 290 0 43 61 0 10 10 159 617 702

2040 135 92 93 19 26 27 34 443 488 8 61 69 25 535 665 0 105 150 0 55 55 222 1,317 1,547

figure 6.9.5 | other asia: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 7,000 OCEAN ENERGY

6,000

CSP GEOTHERMAL

5,000

TWh/a

table 6.9.1 | other asia: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios in gw

the development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. this trend will more than compensate for the phasing out of nuclear power production in the energy [r]evolution scenarios, continuously reducing the number of fossil fuelfired power plants as well. By 2050, 92% of the electricity produced in other asia will come from renewable energy sources in the basic energy [r]evolution scenario. ‘new’ renewables – mainly wind, Pv, csP and geothermal energy – will contribute 73% to the total electricity generation. already by 2020 the share of renewable electricity production will be 25% and 60% by 2030. the installed capacity of renewables will reach about 620 gW in 2030 and 1,930 gW by 2050.

BIOMASS PV

4,000

WIND HYDRO

3,000

HYDROGEN NUCLEAR

2,000

DIESEL OIL GAS

1,000

LIGNITE COAL

166

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2050 168 102 102 26 35 34 62 645 769 11 83 93 39 801 1,030 1 159 311 0 110 110 308 1,935 2,450

energy

[r]evolution

6.9.3 future costs of electricity generation

6.9.4 future investments in the power sector

figure 6.9.6 shows that the introduction of renewable technologies under both energy [r]evolution scenarios increases the future costs of electricity generation compared to the reference scenario until 2030. this difference in full cost of generation will be less than 0.1 Us$ct/kWh in the basic energy [r]evolution and about 0.4 Us$ct/kWh in the advanced scenario, without taking into account integration costs for storage or other load-balancing measures. Because of increasing prices for conventional fuels, electricity generation costs will become economically favourable starting in 2030 under the energy [r]evolution scenarios. By 2050, the cost will be 2.3/1.4 Us$ct/kWh, respectively, below those in the reference case.

around Us$ 5,020 billion is required in investment for the energy [r]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 129 billion per year, Us$ 3,250 billion more than in the reference scenario (Us$ 1,770 billion). investments for the advanced scenario add up to Us$ 6,270 billion until 2050, on average Us$ 161 billion per year, including high investments in additional power plants for the production of synthetic fuels. Under the reference scenario, the levels of investment in conventional power plants add up to almost 57% while approximately 43% would be invested in renewable energies and cogeneration until 2050.

Under the energy [r]evolution scenarios, however, other asia would shift almost 93%/95% of the entire investment towards renewables and cogeneration, respectively. By 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants.

increasing energy efficiency and shifting energy supply to renewables lead to long term costs for electricity supply that are 8% higher in the basic energy [r]evolution scenario than in the reference scenario, due to a 12% increase in electricity production. the advanced scenario with 100% renewable power and an increase in power generation of 44% results in supply costs 30% higher than the reference case.

figure 6.9.6 | other asia: development of total electricity supply costs & of specific electricity generation costs in the scenarios Billion $

Because renewable energy has no fuel costs, the fuel cost savings in the basic energy [r]evolution scenario reach a total of Us$ 3,810 billion up to 2050, Us$ 98 billion per year. the total fuel cost savings therefore would cover 120% of the total additional investments compared to the reference scenario. fuel cost savings in the advanced scenario are even higher and add up to Us$ 4,010 billion, or Us$ 103 billion per year. renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.9.7 | other asia: investment shares reference versus energy [r]evolution scenarios

US$ct/kWh

800

FOSSIL,

700

56% 42%

RENEWABLE,

ref 2012-2050

TOTAL

1,770 BILLION USD

600

CHP, 1% NUCLEAR,

500

300

200

e[r] 2012-2050

TOTAL

5,020 BILLION

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

RENEWABLE,

88%

USD

100

FOSSIL, 7% CHP, 5%

400

FOSSIL, 5% CHP, 4%

adv e[r] 2012-2050

TOTAL

6,270 BILLION

RENEWABLE,

91%

USD

167

world energy [r]evolution a sustainable world energy outlook

6.9.5 energy supply for heating table 6.9.2 | other asia: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in pj /a

today, renewables meet around 42% of other asia’s energy demand for heat, the main contribution coming from the use of biomass. dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. in the basic energy [r]evolution scenario, renewables already provide 56% of other asia’s total heat demand in 2030 and 86% in 2050.

ref e[r] adv

solar Heating

ref e[r]

• energy efficiency measures help to reduce the currently growing energy demand for heating by 28 % in 2050 (relative to the reference scenario), in spite of improving living standards and economic growth.

adv geotHermal Heat ref and Heat PUmPs

e[r] adv

Hydrogen

ref e[r] adv ref

total

e[r] adv

2012 4,215 4,215 4,215 4 4 4 0 0 0 0 0 0 4,219 4,219 4,219

2020 4,583 4,756 4,756 41 446 446 0 545 545 0 0 0 4,624 5,747 5,747

2030 4,651 4,386 4,386 55 1,131 1,131 0 1,068 1,068 0 0 0 4,706 6,585 6,585

2040 4,820 3,587 3,658 96 2,529 2,529 0 2,049 2,048 0 17 358 4,916 8,182 8,593

2050 4,780 3,173 3,353 154 3,179 3,703 0 3,287 3,271 0 657 1,431 4,934 10,296 11,759

• a shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of co 2 emissions. table 6.9.2 shows the development of different renewable technologies for heating in other asia over time. Up to 2030 biomass remains the main contributor of the growing market share. after 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will further reduce the dependence on fossil fuels. the advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.9.8 | other asia: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 25,000

20,000

15,000 PJ/a

Biomass

EFFICIENCY

10,000

HYDROGEN ELECTRIC HEATING GEOTHERMAL HEATING

& HEAT PUMPS

5,000

SOLAR HEATING BIOMASS FOSSIL

168

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.9.6 future investments in the heating sector

also in the heating sector the energy [r]evolution scenarios would require a major revision of current investment strategies in heating technologies. in particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. the use of biomass for heating purposes - often traditional biomass today - will be substantially reduced in the energy [r]evolution scenarios and replaced by more efficient and sustainable renewable heating technologies. renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. thus, it can only be roughly estimated that the energy [r]evolution scenario in total requires around Us$ 1,490 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 38 billion per year. the advanced scenario assumes an even more ambitious expansion of renewable technologies resulting in an average investment of around Us$ 41 billion per year, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with hydrogen or other synthetic fuels.

table 6.9.3 | other asia: installed capacities for renewable heat generation under the scenarios in gw

Biomass

ref e[r] adv

geotHermal

ref e[r] adv

solar Heating

ref e[r] adv

Heat PUmPs

ref e[r] adv

total*

ref e[r] adv

2012 1,971 1,971 1,971 0 0 0 1 1 1 0 0 0 1,973 1,973 1,973

2020 1,947 2,081 2,081 0 17 17 8 33 33 0 0 0 1,955 2,131 2,131

2030 1,848 1,696 1,696 0 45 45 17 349 349 0 64 64 1,865 2,154 2,154

2040 1,737 1,263 1,294 0 88 88 30 780 780 0 119 119 1,767 2,250 2,281

2050 1,565 941 986 0 117 116 48 981 1,143 0 221 220 1,613 2,260 2,465

* excluding direct electric heating.

figure 6.9.9 | other asia: development of investments for renewable heat generation technologies â&#x20AC;&#x201C; reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050 SOLAR,

e[r] 2012-2050

adv e[r] 2012-2050

BIOMASS,

10%

GEOTHERMAL, HEAT PUMPS, TOTAL

TOTAL

142 BILLION USD

90%

22%

GEOTHERMAL,

30%

HEAT PUMPS,

20% 28%

TOTAL

1,500 BILLION USD

BIOMASS,

1,590 BILLION USD SOLAR,

39%

SOLAR,

43%

169

world energy [r]evolution a sustainable world energy outlook

6.9.7 future employment in the energy sector

the advanced Energy [R]evolution scenario results in more energy sector jobs in other asia at every stage of the projection.

figure 6.9.10 | other asia: employment in the energy sector under the reference and advanced energy [r]evolution scenario

• there are 4.3 million energy sector jobs in the advanced energy [r]evolution in 2020, and 3.6 million in the reference scenario.

• in 2030, there are 6.5 million jobs in the advanced energy [r]evolution scenario and 3.3 million in the reference scenario. figure 6.9.10 shows the change in job numbers under both scenarios for each technology between 2015 and 2030. Jobs in the reference scenario remain fairly stable after 2020, and are 1% above 2015 levels at 2030.

6.0

Direct jobs - Millions

• in 2025, there are 6.2 million jobs in the advanced energy [r]evolution scenario, and 3.5 million in the reference scenario.

7.0

strong growth in renewable energy in the advanced energy [r]evolution scenario offsets the virtual disappearance of coal and leads to an increase of 32% in total energy sector jobs by 2020. continued growth leads to energy jobs reaching double 2015 levels in 2030. renewable energy accounts for 85% of energy sector jobs in 2030, with solar pV having the largest share (23%), followed by solar heating and then biomass.

5.0 4.0 3.0 2.0 1.0 0

2015

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

table 6.9.4 | other asia: total employment in the energy sector

& HEAT PUMP

- HEAT

2025

2030

ADV E[R] WIND HYDRO

OCEAN

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

& DIESEL

in thousand jobs

advanced energy [r]evolution

reference

2015

2020

2025

2030

2020

2025

2030

783 850 38 1,578 3,248

870 988 37 1,697 3,592

816 1,033 31 1,610 3,490

946 970 28 1,329 3,272

126 969 20 3,166 4,281

90 995 20 5,112 6,217

45 905 17 5,562 6,528

671 306 349 1,812 111 3,248

749 350 433 1,985 75 3,592

670 320 484 1,983 33 3,490

708 350 467 1,747 3,272

1,154 488 547 2,021 71 4,281

2,328 1,045 849 1,963 32 6,217

2,579 1,277 1,105 1,568 6,528

jobs by fuel

coal gas, oil

diesel

nuclear renewables total jobs jobs by sector

construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs

170

energy

[r]evolution

6.9.8 transport table 6.9.5 | other asia: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in pj /a

in 2050, the car fleet in other asia will be significantly larger than today. therefore a key target is the successful introduction of highly efficient vehicle concepts. in addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the expanding large metropolitan areas. along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the reference scenario. due to population increase, gdP growth and higher living standards, energy demand from the transport sector is expected to strongly increase in the reference scenario by around 108% to 12,220 PJ/a in 2050. in the basic energy [r]evolution scenario, efficiency measures and modal shifts will save 49% (5,940 PJ/a) in 2050 compared to the reference scenario.

rail

ref e[r] adv

road

ref e[r] adv

domestic aviation ref e[r] adv domestic

ref

navigation

e[r] adv

additional modal shifts and technology switches lead to even higher energy savings in the advanced scenario of 57% (6,920 PJ/a) in 2050 compared to the reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. By 2030, electricity will provide 7% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the energy [r]evolution, while in 2050 the share will be 36% (46% in the advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. in 2050, up to 1,750 PJ/a of hydrogen is used in the transport sector for the advanced energy [r]evolution scenario.

ref

total

e[r] adv

2012 65 65 65 5,471 5,471 5,471 172 172 172 177 177 177 5,886 5,886 5,886

2020 105 83 83 7,738 6,650 6,650 318 212 212 264 200 200 8,425 7,144 7,144

2030 122 108 237 8,601 7,202 6,676 384 264 256 300 235 235 9,407 7,808 7,403

2040 159 136 408 10,138 7,129 6,098 507 345 321 372 213 213 11,177 7,824 7,040

2050 199 160 559 10,927 5,398 4,126 652 499 399 444 221 221 12,222 6,278 5,305

figure 6.9.11 | other asia: final energy consumption in transport under the scenarios

14,000

12,000

10,000

PJ/a

8,000

6,000

EFFICIENCY HYDROGEN

4,000

ELECTRICITY SYNFUELS BIOFUELS

2,000

NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

171

world energy [r]evolution a sustainable world energy outlook

6.9.10 development of co 2 emissions

CO2 emissions [Mt/a]

Population (million) 1,600

5,000 4,500

1,400

4,000

1,200

3,500

1,000

3,000

With a 39% share of co 2, the industry sector will be the largest source of emissions in 2050 in the basic energy [r]evolution scenario. By 2050, other asia´s co 2 emissions are around 52% below 1990 levels in the energy [r]evolution scenario while energy consumption is fully decarbonised in the advanced case.

2,500

800

2,000

600

1,500

400

1,000

200

500 0

6.9.11 primary energy consumption

taking into account the assumptions discussed above, the resulting primary energy consumption under the energy [r]evolution scenarios is shown in figure 6.9.12. Under the basic energy [r]evolution scenario, primary energy demand will increase by 29% from today’s 35,530 PJ/a to around 46,000 PJ/a. compared to the reference scenario, overall primary energy demand will be reduced by 43% in 2050 under the energy [r]evolution scenario (reference scenario: around 80,000 PJ in 2050). the advanced scenario results due to additional conversion losses in a primary energy consumption of around 46,900 PJ in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

expansion of renewable energies and a fast introduction of very efficient vehicle concepts in the transport sector to replace oil based combustion engines. this leads to an overall renewable primary energy share of 43% in 2030 and 79% in 2050 in the basic energy [r]evolution and of more than 91% in 2050 in the advanced case (incl. non-energy consumption). in contrast to the reference scenario, no new nuclear power plants will be built in other asia in the energy [r]evolution scenarios.

the energy [r]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by

figure 6.9.12 | other asia: projection of total primary energy demand (ped) by energy carrier including electricity import balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 90,000 80,000 70,000

EFFICIENCY OCEAN ENERGY

60,000

GEOTHERMAL

PJ/a

figure 6.9.13 | other asia: development of co2 emissions by sector under the energy [r]evolution scenarios ‘savings ’ = reduction compared to the reference scenario

Whilst other asia’s emissions of co 2 will increase by 173% between 2012 and 2050 under the reference scenario, under the energy [r]evolution scenario they will decrease from 1,740 million tonnes in 2012 to 338 million tonnes in 2050. annual per capita emissions will drop from 1.6 tonne to 0.2 tonne. in spite of the abstinence of nuclear power production and increasing power demand, co 2 emissions will decrease in the electricity sector. in the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well.

50,000

SOLAR BIOMASS

40,000

WIND HYDRO

30,000

NATURAL GAS

20,000

CRUDE OIL COAL

10,000

NUCLEAR NET ELECTRICITY IMPORTS

172

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.9.6 | other asia: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

54.7 -114.1 -59.4

157.1 -961.0 -803.9

209.5 -1,352.7 -1,143.2

235.9 -1,487.3 -1,251.5

657.1 -3,915.1 -3,258.0

16.8 -100.4 -83.5

$ $ $ $ $ $

0.7 -8.9 8.4 1.7 1.6 3.5

24.1 109.8 191.0 25.6 7.9 358.4

39.5 513.1 567.9 46.6 10.5 1,177.5

20.0 1,278.6 894.2 62.9 12.8 2,268.5

84.3 1,892.6 1,661.5 136.9 32.8 3,808.0

2.2 48.5 42.6 3.5 0.8 97.6

average per year nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.9.7 | other asia: accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

125.4

312.7

376.5

538.7

1,353.3

2012 - 2050 average per year

34.7

table 6.9.8 | other asia: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs advanced e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

56.2 -115.0 -58.8

166.8 -1,169.1 -1,002.3

204.1 -1,630.9 -1,426.8

249.5 -2,262.4 -2,012.9

676.6 -5,177.4 -4,500.9

17.3 -132.8 -115.4

$ $ $ $ $ $

0.7 -14.6 10.3 1.7 1.6 -0.3

28.8 69.0 217.4 25.6 7.9 348.7

44.7 500.2 593.2 46.6 10.5 1,195.1

23.1 1,468.9 899.7 63.1 12.8 2,467.6

97.3 2,023.5 1,720.5 137.1 32.8 4,011.1

2.5 51.9 44.1 3.5 0.8 102.8

average per year

nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative advanced e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.9.9 | other asia: accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs advanced e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

125.6

312.6

375.6

637.0

1,450.8

2012 - 2050 average per year

37.2

173

world energy [r]evolution a sustainable world energy outlook

6.10 china this reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. the transformation to a carbon free energy system in the advanced scenario will further increase the electricity demand in 2050 up to 9,200 tWh/a. electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. around 1,710 tWh are used in 2050 for electric vehicles and rail transport in 2050 in the advanced scenario, around 500 tWh for hydrogen and 950 tWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.10.1 final energy demand by sector

efficiency gains in the heating sector are very large as well. Under the energy [r]evolution scenarios, consumption equivalent to about 15,500 PJ/a is avoided through efficiency gains by 2050 compared to the reference scenario. as a result of energy-related renovation of the existing stock of residential buildings, the introduction of low energy standards and ‘passive climatisation’ for new buildings, as well as highly efficient air conditioning systems, enjoyment of the same comfort and energy services will be accompanied with much lower future energy demand.

Under both energy [r]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.10.2). total electricity demand will rise from about 4,170 tWh/a to 8,730 tWh/a by 2050 in the basic energy [r]evolution scenario. compared to the reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 4,760 tWh/a.

figure 6.10.1 | china: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat from chp autoproducers 120,000

100,000

80,000

PJ/a

combining the projections on population development, gdP growth and energy intensity results in future development pathways for china’s final energy demand. these are shown in figure 6.10.1 for the reference and energy [r]evolution scenarios. Under the reference scenario, total final energy demand increases by 70% from the current 65,900 PJ/a to 111,800 PJ/a in 2050. in the basic energy [r]evolution scenario, final energy demand decreases by 7% compared to current consumption and is expected to reach 61,000 PJ/a by 2050. the advanced scenario results in some additional reductions due to a higher share of electric cars.

60,000

40,000 EFFICIENCY

20,000

OTHER SECTORS INDUSTRY TRANSPORT

174

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.10.2 | china: development of electricity demand by sector in the energy [r]evolution scenarios

figure 6.10.4 | china: development of final energy demand for heat by sector in the energy [r]evolution scenarios 60,000

45,000 40,000

50,000

35,000 40,000

25,000

PJ/a

30,000

20,000

30,000

20,000

15,000 10,000

10,000

5,000 0

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.10.3 | china: development of the final energy demand for transport by sector in the energy [r]evolution scenarios 30,000

25,000

PJ/a

20,000

15,000

10,000

5,000

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

175

world energy [r]evolution a sustainable world energy outlook

6.10.2 electricity generation

Hydro

ref e[r] adv

Biomass

ref e[r] adv

Wind

ref e[r] adv

geotHermal

ref e[r] adv

a 100% electricity supply from renewable energy resources in the advanced scenario leads to around 4,740 gW installed generation capacity in 2050.

ref e[r] adv

csP

table 6.10.1 shows the comparative evolution of the different renewable technologies in china over time. Up to 2020 wind and Pv will become the main contributors to the growing market share. after 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. the energy [r]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 21% to 23% by 2030 and up to 47% by 2050. therefore, smart grids, demand side management (dsm), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

ref e[r] adv

ocean

ref e[r] adv

total

ref e[r] adv

2012 249 249 249 6 6 6 75 75 75 0 0 0 7 7 7 0 0 0 0 0 0 337 337 337

2020 360 360 360 30 31 31 183 195 205 0 0 0 81 131 146 0 0 1 0 0 0 655 718 744

2030 406 381 381 46 106 106 269 498 582 0 13 19 124 483 612 1 39 114 0 4 5 847 1,523 1,819

2040 434 399 399 55 164 164 312 884 1,220 1 53 79 155 892 1,208 5 154 429 1 21 27 962 2,565 3,525

2050 461 418 427 64 194 203 362 1,181 1,604 2 81 137 186 1,232 1,626 10 249 678 1 52 62 1,087 3,407 4,736

figure 6.10.5 | china: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 16,000 OCEAN ENERGY

14,000

CSP

12,000

GEOTHERMAL BIOMASS

10,000 TWh/a

table 6.10.1 | china: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios in gw

the development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. this trend will more than compensate for the phasing out of nuclear power production in the energy [r]evolution scenarios, continuously reducing the number of fossil fuelfired power plants as well. By 2050, 87% of the electricity produced in china will come from renewable energy sources in the basic energy [r]evolution scenario. ‘new’ renewables – mainly wind, Pv, csP and geothermal energy – will contribute 58% to the total electricity generation. already by 2020 the share of renewable electricity production will be 26% and 44% by 2030. the installed capacity of renewables will reach about 1,520 gW in 2030 and 3,410 gW by 2050.

PV WIND

8,000

HYDRO HYDROGEN

6,000

NUCLEAR DIESEL

4,000

OIL GAS

2,000

LIGNITE COAL

176

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.10.3 future costs of electricity generation

6.10.4 future investments in the power sector

figure 6.10.6 shows that the introduction of renewable technologies under both energy [r]evolution scenarios decreases the future costs of electricity generation compared to the reference scenario already by 2020. this difference in full cost of generation will be in 2030 already 1.0 Us$ct/kWh in the basic energy [r]evolution and 0.6 Us$ct/kWh in the advanced scenario, without taking into account integration costs for storage or other load-balancing measures. Because of increasing prices for conventional fuels, electricity generation costs will become economically favourable starting in 2020 under the energy [r]evolution scenarios. By 2050, the cost will be 1.5/0.2 Us$ct/kWh, respectively, below those in the reference case.

around Us$ 8,470 billion is required in investment for the energy [r]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 217 billion per year, Us$ 3,130 billion more than in the reference scenario (Us$ 5,340 billion). investments for the advanced scenario add up to Us$ 12,430 billion until 2050, on average Us$ 319 billion per year, including high investments in additional power plants for the production of synthetic fuels. Under the reference scenario, the levels of investment in conventional power plants add up to almost 49% while approximately 51% would be invested in renewable energies and cogeneration until 2050.

Under the reference scenario, on the other hand, growth in demand and increasing fossil fuel prices result in total electricity supply costs rising from todayâ&#x20AC;&#x2122;s Us$ 311 billion per year to more than Us$ 1,125 billion in 2050, compared to Us$ 813 billion in the basic and Us$ 1,268 billion in the advanced energy [r]evolution scenario. figure 6.10.6 shows that both energy [r]evolution scenarios not only comply with chinaÂ´s co 2 reduction targets, but also help stabilise energy costs and relieve the economic pressure on society. increasing energy efficiency and shifting energy supply to renewables lead to long term costs for electricity supply that are more than 28% lower in the basic energy [r]evolution scenario than in the reference scenario. the advanced scenario with 100% renewable power and an increase in power generation of 10% results in supply costs 13% higher than the reference case.

figure 6.10.6 | china: development of total electricity supply costs & of specific electricity generation costs in the scenarios Billion $

Under the energy [r]evolution scenarios, however, china would shift up to 95% of the entire investment towards renewables and cogeneration, respectively. By 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants. Because renewable energy has no fuel costs, the fuel cost savings in the basic energy [r]evolution scenario reach a total of Us$ 8,840 billion up to 2050, Us$ 227 billion per year. the total fuel cost savings therefore would cover 280% of the total additional investments compared to the reference scenario. fuel cost savings in the advanced scenario are even higher and add up to Us$ 9,610 billion, or Us$ 246 billion per year. renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.10.7 | china: investment shares reference versus energy [r]evolution scenarios

US$ct/kWh

FOSSIL,

40% 39%

1,600

1,400

1,200

1,000

CHP, 12% NUCLEAR, 9%

800

FOSSIL,

600

400

200

RENEWABLE,

ref 2012-2050

TOTAL

5,540 BILLION USD

CHP,

e[r] 2012-2050

TOTAL

8,460 BILLION USD

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

RENEWABLE,

FOSSIL, CHP,

adv e[r] 2012-2050

19% 75%

14%

TOTAL

12,430 BILLION USD

RENEWABLE,

81%

177

world energy [r]evolution a sustainable world energy outlook

6.10.5 energy supply for heating table 6.10.2 | china: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in pj /a

today, renewables meet around 19% of china’s energy demand for heating, the main contribution coming from the use of biomass. dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. in the basic energy [r]evolution scenario, renewables already provide 34% of china’s total heat demand in 2030 and 82% in 2050.

ref e[r] adv

solar Heating

ref e[r]

• energy efficiency measures help to reduce the currently growing energy demand for heating by 31% in 2050 (relative to the reference scenario), in spite of improving living standards and economic growth.

adv geotHermal Heat ref and Heat PUmPs

e[r] adv

Hydrogen

ref e[r] adv ref

total

e[r] adv

2012 6,221 6,221 6,221 539 539 539 256 256 256 0 0 0 7,016 7,016 7,016

2020 5,131 6,989 6,989 928 1,713 1,713 454 1,389 1,389 0 0 42 6,513 10,091 10,133

2030 4,832 7,448 7,448 1,036 2,716 2,716 527 2,903 2,903 0 13 194 6,395 13,079 13,261

2040 4,539 7,949 7,949 1,114 5,427 5,427 746 7,137 7,263 0 520 1,458 6,399 21,033 22,097

2050 4,382 8,425 9,068 1,207 5,859 5,711 1,029 8,908 9,925 0 1,469 5,297 6,618 24,661 30,002

• a shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of co 2 emissions. table 6.10.2 shows the development of different renewable technologies for heating in china over time. Up to 2030 biomass remains the main contributor of the growing market share. after 2030, the continuing growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen will further reduce the dependence on fossil fuels. the advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.10.8 | china: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 60,000

50,000

40,000

PJ/a

Biomass

30,000 EFFICIENCY HYDROGEN

20,000

ELECTRIC HEATING GEOTHERMAL HEATING

& HEAT PUMPS

10,000

SOLAR HEATING BIOMASS FOSSIL

178

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.10.6 future investments in the heating sector

also in the heating sector the energy [r]evolution scenarios would require a major revision of current investment strategies in heating technologies. in particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. the use of biomass for heating purposes - often traditional biomass today - will be substantially reduced in the energy [r]evolution scenarios and replaced by more efficient and sustainable renewable heating technologies. renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. thus, it can only be roughly estimated that the energy [r]evolution scenario in total requires around Us$ 3,310 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 85 billion per year. the advanced scenario assumes an even more ambitious expansion of renewable technologies resulting in an average investment of around Us$ 86 billion per year, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with hydrogen or other synthetic fuels.

table 6.10.3 | china: installed capacities for renewable heat generation under the scenarios in gw

Biomass

ref e[r] adv

geotHermal

ref e[r] adv

solar Heating

ref e[r] adv

Heat PUmPs

ref e[r] adv

total*

ref e[r] adv

2012 2,876 2,876 2,876 0 0 0 159 159 159 46 46 46 3,082 3,082 3,082

2020 2,442 2,556 2,556 0 0 0 243 279 279 69 87 87 2,754 2,923 2,923

2030 2,001 2,243 2,243 0 78 78 307 768 768 96 274 274 2,403 3,362 3,362

2040 1,729 1,695 1,695 0 262 262 333 1,549 1,549 135 482 505 2,197 3,988 4,011

2050 1,501 1,460 1,624 0 366 384 365 1,676 1,634 187 564 621 2,053 4,066 4,263

* excluding direct electric heating.

figure 6.10.9 | china: development of investments for renewable heat generation technologies â&#x20AC;&#x201C; reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050

e[r] 2012-2050

BIOMASS,

adv e[r] 2012-2050

BIOMASS,

15%

GEOTHERMAL, HEAT PUMPS, TOTAL

584 BILLION USD

SOLAR,

18%

HEAT PUMPS,

TOTAL

23%

GEOTHERMAL,

39%

HEAT PUMPS,

23% 42%

TOTAL

3,310 BILLION USD

67%

BIOMASS,

3,344 BILLION USD SOLAR,

32%

SOLAR,

29%

179

world energy [r]evolution a sustainable world energy outlook

6.10.7 future employment in the energy sector

the advanced Energy [R]evolution scenario results in more energy sector jobs in China from 2025 onwards, despite substantial reductions in fossil fuel jobs in both scenarios. • there are 6.9 million energy sector jobs in both the advanced energy [r]evolution and reference scenarios in 2020.

9.0

• in 2025, there are 7.9 million jobs in the advanced energy [r]evolution scenario, and 6.2 million in the reference scenario.

7.0

• in 2030, there are 8 million jobs in the advanced energy [r]evolution scenario and 4.9 million in the reference scenario. figure 6.10.10 shows the change in job numbers under both scenarios for each technology between 2015 and 2030. Jobs in the coal sector decline sharply in both scenarios, reflecting substantial increases in productivity in china’s coal industry.

8.0

Direct jobs - Millions

figure 6.10.10 | china: employment in the energy sector under the reference and advanced energy [r]evolution scenario

strong growth in the renewable sector compensates for some of the losses in the coal industry, so while jobs in the advanced energy [r]evolution scenario are below 2015 levels, they are 1.8 million higher than jobs in the reference scenario in 2025 and 3 million higher in 2030. renewable energy accounts for 74% of energy jobs by 2030 in the advanced energy [r]evolution scenario.

table 6.10.4 | china: total employment in the energy sector

6.0 5.0 4.0 3.0 2.0 1.0 0

2015

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

& HEAT PUMP

- HEAT

2025

2030

ADV E[R] WIND HYDRO

OCEAN

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

& DIESEL

in thousand jobs

advanced energy [r]evolution

reference

2015

2020

2025

2030

2020

2025

2030

4,985 274 178 1,964 7,402

4,462 371 253 1,739 6,825

3,832 473 223 1,560 6,088

3,029 565 170 1,175 4,939

2,950 510 53 3,382 6,895

2,016 644 46 5,230 7,936

1,238 788 32 5,903 7,961

1,689 868 720 4,125 7,402

1,495 732 998 3,600 6,825

1,294 659 1,075 3,060 6,088

868 440 1,039 2,591 4,939

1,222 1,037 1,059 3,577 6,895

2,115 1,570 1,373 2,879 7,936

2,336 1,722 1,653 2,250 7,961

jobs by fuel

coal gas, oil

diesel

nuclear renewables total jobs jobs by sector

construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs

180

energy

[r]evolution

6.10.8 transport table 6.10.5 | china: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in pj /a

in 2050, the car fleet in china will be significantly larger than today. therefore a key target is the successful introduction of highly efficient vehicle concepts. in addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the expanding large metropolitan areas. along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the reference scenario. due to population increase, gdP growth and higher living standards, energy demand from the transport sector is expected to strongly increase in the reference scenario by around 158% to 25,920 PJ/a in 2050. in the basic energy [r]evolution scenario, efficiency measures and modal shifts will save 50% (12,860 PJ/a) in 2050 compared to the reference scenario.

rail

ref e[r] adv

road

ref e[r] adv

domestic aviation ref e[r] adv domestic

ref

navigation

e[r] adv

additional modal shifts and technology switches lead to even higher energy savings in the advanced scenario of 61% (15,940 PJ/a) in 2050 compared to the reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. By 2030, electricity will provide 8% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the energy [r]evolution, while in 2050 the share will be 46% (62% in the advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. in 2050, up to 1,380 PJ/a of hydrogen is used in the transport sector for the advanced energy [r]evolution scenario.

ref

total

e[r] adv

2012 582 582 582 8,149 8,149 8,149 513 513 513 806 806 806 10,051 10,051 10,051

2020 795 742 759 15,204 11,524 11,436 1,082 870 861 1,019 930 930 18,100 14,066 13,987

2030 835 790 1,049 18,338 13,575 12,250 1,184 1,000 930 1,191 1,060 1,030 21,547 16,425 15,259

2040 927 850 1,522 20,217 12,120 9,035 1,260 880 695 1,321 1,110 1,000 23,725 14,960 12,252

2050 1,039 950 2,105 22,234 10,290 6,500 1,279 800 520 1,352 1,010 850 25,903 13,050 9,975

figure 6.10.11 | china: final energy consumption in transport under the scenarios

30,000

25,000

PJ/a

20,000

15,000 EFFICIENCY HYDROGEN

10,000

ELECTRICITY SYNFUELS

5,000

BIOFUELS NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

181

world energy [r]evolution a sustainable world energy outlook

6.10.10 development of co 2 emissions

CO2 emissions [Mt/a]

Population (million

14,000

1,600

12,000

1,400 1,200

10,000

1,000

8,000

With a 40% share of co 2, the industry sector will be the largest source of emissions in 2050 in the basic energy [r]evolution scenario. By 2050, china´s co 2 emissions are around 42% below 1990 levels in the energy [r]evolution scenario while energy consumption is fully decarbonised in the advanced case.

800 6,000

600

4,000

400

2,000

200

6.10.11 primary energy consumption

taking into account the assumptions discussed above, the resulting primary energy consumption under the energy [r]evolution scenarios is shown in figure 6.10.12. Under the basic energy [r]evolution] scenario, primary energy demand will decrease by 20% from today’s 114,450 PJ/a to around 91,000 PJ/a. compared to the reference scenario, overall primary energy demand will be reduced by 55% in 2050 under the energy [r]evolution scenario (reference scenario: around 203,000 PJ in 2050). the advanced scenario results due to additional conversion losses in a primary energy consumption of around 95,300 PJ in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

expansion of renewable energies and a fast introduction of very efficient vehicle concepts in the transport sector to replace oil based combustion engines. this leads to an overall renewable primary energy share of 23% in 2030 and 71% in 2050 in the basic energy [r]evolution and of more than 92% in 2050 in the advanced case (incl. non-energy consumption). in contrast to the reference scenario, no new nuclear power plants will be built in china in the energy [r]evolution scenarios.

the energy [r]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by

figure 6.10.12 | china: projection of total primary energy demand (ped) by energy carrier including electricity import balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 250,000

200,000 EFFICIENCY OCEAN ENERGY GEOTHERMAL

150,000

SOLAR

PJ/a

figure 6.10.13 | china: development of co 2 emissions by sector under the energy [r]evolution scenarios ‘ savings ’ = reduction compared to the reference scenario

Whilst china’s emissions of co 2 will increase by 58% between 2012 and 2050 under the reference scenario, under the energy [r]evolution scenario they will decrease from 8,230 million tonnes in 2012 to 1,319 million tonnes in 2050. annual per capita emissions will drop from 5.9 tonne to 0.9 tonne. in spite of the abstinence of nuclear power production and increasing power demand, co 2 emissions will decrease in the electricity sector. in the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well.

BIOMASS WIND

100,000

HYDRO NATURAL GAS CRUDE OIL

50,000

COAL NUCLEAR NET ELECTRICITY IMPORTS

182

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.10.6 | china: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

109.0 -115.5 -6.5

725.2 -1,055.6 -330.4

637.0 -1,873.5 -1,236.5

539.9 -2,155.2 -1,615.3

2,011.1 -5,199.7 -3,188.7

51.6 -133.3 -81.8

$ $ $ $ $ $

0.3 7.1 20.1 0.0 7.5 35.0

3.8 39.7 1,008.2 0.0 63.8 1,115.4

6.2 193.2 2,784.0 0.0 129.5 3,112.9

7.2 396.6 3,958.5 0.0 210.7 4,573.0

17.4 636.6 7,770.9 0.0 411.4 8,836.3

0.4 16.3 199.3 0.0 10.5 226.6

average per year nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.10.7 | china: accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

80.2

591.9

1,201.3

857.4

2,730.8

2012 - 2050 average per year

70.0

table 6.10.8 | china: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs advanced e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

109.3 -160.1 -50.8

734.4 -1,749.9 -1,015.4

628.2 -3,605.6 -2,977.3

401.3 -3,510.4 -3,109.1

1,873.3 -9,025.9 -7,152.7

48.0 -231.4 -183.4

$ $ $ $ $ $

0.3 7.1 20.4 0.0 7.5 35.2

3.8 43.6 1,024.3 0.0 63.8 1,135.5

6.2 228.4 2,963.7 0.0 129.5 3,327.8

7.2 671.5 4,219.5 0.0 210.7 5,108.9

17.4 950.7 8,227.9 0.0 411.4 9,607.4

0.4 24.4 211.0 0.0 10.5 246.3

average per year

nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative advanced e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.10.9 | china: accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs advanced e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

80.2

591.9

1,238.8

849.6

2,760.5

2012 - 2050 average per year

70.8

183

world energy [r]evolution a sustainable world energy outlook

6.11 oecd asia oceania this reduction can be achieved in particular by introducing highly efficient electronic devices using the best available technology in all demand sectors. the transformation to a carbon free energy system in the advanced scenario will further increase the electricity demand in 2050 up to 1,900 tWh/a. electricity will become the major renewable ‘primary’ energy, not only for direct use for various purposes but also for the generation of synthetic fuels for fossil fuels substitution. around 330 tWh are used in 2050 for electric vehicles and rail transport in 2050 in the advanced scenario, around 210 tWh for hydrogen and 220 tWh for synthetic liquid fuel generation for the transport sector (excluding bunkers).

6.11.1 final energy demand by sector

efficiency gains in the heating sector are large as well. Under the energy [r]evolution scenarios, consumption equivalent to about 3,000 PJ/a is avoided through efficiency gains by 2050 compared to the reference scenario. as a result of energyrelated renovation of the existing stock of residential buildings, the introduction of low energy standards and ‘passive climatisation’ for new buildings, as well as highly efficient air conditioning systems, enjoyment of the same comfort and energy services will be accompanied by much lower future energy demand.

Under both energy [r]evolution scenarios, due to economic growth, increasing living standards and electrification of the transport sector, overall electricity demand is expected to increase despite efficiency gains in all sectors (see figure 6.11.2). total electricity demand will rise from about 1,650 tWh/a to 1,720 tWh/a by 2050 in the basic energy [r]evolution scenario. compared to the reference scenario, efficiency measures in the industry, residential and service sectors avoid the generation of about 940 tWh/a.

figure 6.11.1 | oecd asia oceania: projection of total final energy demand by sector – reference, energy [r]evolution, advanced energy [r]evolution scenarios without non - energy use and heat from chp autoproducers 25,000

20,000

15,000 PJ/a

combining the projections on population development, gdP growth and energy intensity results in future development pathways for oecd asia oceania’s final energy demand. these are shown in figure 6.11.1 for the reference and energy [r]evolution scenarios. Under the reference scenario, total final energy demand increases by 2% from the current 20,100 PJ/a to 20,600 PJ/a in 2050. in the basic energy [r]evolution scenario, final energy demand decreases by 43% compared to current consumption and is expected to reach 11,500 PJ/a by 2050. the advanced scenario results in some additional reductions due to a higher share of electric cars.

10,000

EFFICIENCY

5,000

OTHER SECTORS INDUSTRY TRANSPORT

184

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

figure 6.11.2 | oecd asia oceania: development of electricity demand by sector in the energy [r]evolution scenarios

figure 6.11.4 | oecd asia oceania: development of final energy demand for heat by sector in the energy [r]evolution scenarios

9,000

10,000

8,000

9,000 8,000

7,000

6,000

5,000

PJ/a

4,000

5,000 4,000

3,000

2,000

1,000

1,000 0

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

2012

2020

2025

2030

2040

2050

EFFICIENCY

TRANSPORT

OTHER SECTORS

INDUSTRY

figure 6.11.3 | oecd asia oceania: development of the final energy demand for transport by sector in the energy [r]evolution scenarios 6,000

5,000

PJ/a

4,000

3,000

2,000

1,000

0 E[R] ADV E[R]

E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY

ROAD (HDV)

DOMESTIC NAVIGATION

ROAD (PC

DOMESTIC AVIATION

RAIL

& LDV)

185

world energy [r]evolution a sustainable world energy outlook

6.11.2 electricity generation

Hydro

ref e[r] adv

Biomass

ref e[r] adv

Wind

ref e[r] adv

geotHermal

ref e[r] adv

a 100% electricity supply from renewable energy resources in the advanced scenario leads to around 1,250 gW installed generation capacity in 2050.

ref e[r] adv

csP

table 6.11.1 shows the comparative evolution of the different renewable technologies in oecd asia oceania over time. Until 2020 hydro will remain the main renewable power source. after 2020, the continuing growth of wind and Pv will be complemented by electricity from solar thermal, geothermal and ocean energy. the energy [r]evolution scenarios will lead to a high share of fluctuating power generation sources (Pv, wind and ocean) of already 35% to 40% by 2030 and 61% to 66% by 2050. therefore, smart grids, demand side management (dsm), energy storage capacities and other options need to be expanded in order to increase the flexibility of the power system for grid integration, load balancing and a secure supply of electricity.

ref e[r] adv

ocean

ref e[r] adv

total

ref e[r] adv

2012 69 69 69 6 6 6 6 6 6 1 1 1 10 10 10 0 0 0 0 0 0 93 93 93

2020 71 80 80 10 14 14 16 45 55 2 8 8 59 84 101 0 4 7 1 3 3 159 239 268

2030 74 83 83 12 20 23 31 125 143 5 16 23 71 264 315 1 25 30 1 14 28 194 548 644

2040 76 83 83 15 29 29 44 208 248 7 24 39 79 370 496 2 28 34 2 26 48 225 767 976

2050 76 92 92 18 58 39 51 223 310 10 30 49 89 394 637 2 35 50 3 40 76 250 872 1,252

figure 6.11.5 | oecd asia oceania: development of electricity generation structure – reference, energy [r]evolution, advanced energy [r]evolution scenarios 3,500 OCEAN ENERGY

3,000

CSP GEOTHERMAL

2,500

TWh/a

table 6.11.1 | oecd asia oceania: projection of renewable electricity generation capacity under the reference and the energy [r]evolution scenarios in gw

the development of the electricity supply sector is characterised by a dynamically growing renewable energy market and an increasing share of renewable electricity. this trend will more than compensate for the phasing out of nuclear power production in the energy [r]evolution scenarios, continuously reducing the number of fossil fuel-fired power plants as well. By 2050, 95% of the electricity produced in oecd asia oceania will come from renewable energy sources in the basic energy [r]evolution scenario. ‘new’ renewables – mainly wind, Pv, ocean and geothermal energy – will contribute 76% to the total electricity generation. already by 2020 the share of renewable electricity production will be 28% and 58% by 2030. the installed capacity of renewables will reach about 550 gW in 2030 and 870 gW by 2050.

BIOMASS PV

2,000

WIND HYDRO

1,500

HYDROGEN NUCLEAR

1,000

DIESEL OIL GAS

500

LIGNITE COAL

186

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.11.3 future costs of electricity generation

6.11.4 future investments in the power sector

figure 6.11.6 shows that the introduction of renewable technologies under both energy [r]evolution scenarios increases the future costs of electricity generation compared to the reference scenario until 2030. this difference in full cost of generation will be less than 1.8 Us$ct/kWh in the basic energy [r]evolution and about 2.1 Us$ct/kWh in the advanced scenario, without taking into account integration costs for storage or other load-balancing measures. Because of increasing prices for conventional fuels and the lower co2 intensity of electricity generation, electricity generation costs will become economically favourable after 2040 under the energy [r]evolution scenarios. By 2050, the cost will be 3.1/2.7 Us$ct/kWh, respectively, below those in the reference case.

around Us$ 3,120 billion is required in investment for the energy [r]evolution scenario to become reality (including investments for replacement after the economic lifetime of the plants) approximately Us$ 80 billion per year, Us$ 650 billion more than in the reference scenario (Us$ 2,480 billion). investments for the advanced scenario sum up to Us$ 3,950 billion until 2050, on average Us$ 101 billion per year. Under the reference scenario, the levels of investment in conventional power plants add up to almost 62% while approximately 38% would be invested in renewable energies and cogeneration until 2050.

Under the reference scenario, on the other hand, growth in demand and increasing fossil fuel prices result in total electricity supply costs rising from todayâ&#x20AC;&#x2122;s Us$ 183 billion per year to more than Us$ 302 billion in 2050, compared to Us$ 212 billion in the basic and Us$ 301 billion in the advanced energy [r]evolution scenario. figure 6.11.6 shows that both energy [r]evolution scenarios will help to comply with oecd asia oceaniaÂ´s co 2 reduction targets, and eventually will also help to stabilise energy costs. increasing energy efficiency and shifting energy supply to renewables lead to long term investment costs for electricity supply that are more than 30% lower in the basic energy [r]evolution scenario than in the reference scenario. the advanced scenario with 100% renewable power and an increase in power generation of 24% results in supply costs similar to the reference case.

figure 6.11.6 | oecd asia oceania: development of total electricity supply costs & of specific electricity generation costs in the scenarios Billion $

Under the energy [r]evolution scenarios, however, oecd asia oceania would shift almost 88%/90% of the entire investment towards renewables and cogeneration, respectively. By 2030, the fossil fuel share of power sector investment would be focused mainly on gas power plants. Because renewable energy has no fuel costs, the fuel cost savings in the basic energy [r]evolution scenario reach a total of Us$ 2,170 billion up to 2050, Us$ 56 billion per year. the total fuel cost savings therefore would cover 330% of the total additional investments compared to the reference scenario. fuel cost savings in the advanced scenario are even higher and add up to Us$ 2,400 billion, or Us$ 62 billion per year. renewable energy sources would then go on to produce electricity without any further fuel costs beyond 2050, while costs for coal and gas will continue to be a burden on national economies.

figure 6.11.7 | oecd asia oceania: investment shares - reference versus energy [r]evolution scenarios

US$ct/kWh

350

300

250

200

150

FOSSIL,

ref 2012-2050

TOTAL

2,480 BILLION USD

100

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

EFFICIENCY MEASURES E[R]

REFERENCE SCENARIO

EFFICIENCY MEASURES ADV E[R]

SPECIFIC ELECTRICITY GENERATION COSTS REF

ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS E[R]

ADVANCED ENERGY [R]EVOLUTION

SPECIFIC ELECTRICITY GENERATION COSTS ADV E[R]

10%

FOSSIL,

e[r] 2012-2050

TOTAL

3,120 BILLION

0 REF E[R] ADV E[R]

CHP,

NUCLEAR,

USD

24% 27%

RENEWABLE,

CHP,

39%

12%

RENEWABLE,

76%

FOSSIL, CHP,

adv e[r] 2012-2050

10% 8%

TOTAL

3,950 BILLION USD

RENEWABLE,

82%

187

world energy [r]evolution a sustainable world energy outlook

6.11.5 energy supply for heating table 6.11.2 | oecd asia oceania: projection of renewable heat supply under the reference and both energy [r]evolution scenarios in pj /a

today, renewables meet around 5% of oecd asia oceania’s energy demand for heating, the main contribution coming from the use of biomass. dedicated support instruments are required to ensure a dynamic development in particular for renewable technologies for buildings and renewable process heat production. in the basic energy [r]evolution scenario, renewables already provide 35% of oecd asia oceania’s total heat demand in 2030 and 93% in 2050.

ref e[r] adv

solar Heating

ref e[r]

• energy efficiency measures help to reduce the currently growing energy demand for heating by 34% in 2050 (relative to the reference scenario), in spite of improving living standards and economic growth.

adv geotHermal Heat ref and Heat PUmPs

e[r] adv

Hydrogen

ref e[r] adv ref

total

e[r] adv

2012 268 268 268 27 27 27 30 30 30 0 0 0 326 326 326

2020 460 842 842 64 243 243 33 193 193 0 4 4 556 1,282 1,282

2030 501 1,059 1,059 81 495 495 34 360 360 0 11 11 615 1,925 1,925

2040 589 1,543 1,548 131 852 852 36 780 780 0 27 169 757 3,202 3,349

2050 733 2,012 1,758 199 911 921 38 1,233 1,238 0 131 533 970 4,286 4,450

• a shift from coal and oil to natural gas in the remaining conventional applications leads to a further reduction of co 2 emissions. table 6.11.8 shows the development of different renewable technologies for heating in oecd asia oceania over time. Biomass remains the main contributor, with increasing investments in highly efficient modern biomass technology. after 2030, a massive growth of solar collectors and a growing share of geothermal and environmental heat as well as heat from renewable hydrogen can further reduce the dependence on fossil fuels. the advanced scenario results in a complete substitution of the remaining gas consumption by hydrogen generated from renewable electricity.

figure 6.11.8 | oecd asia oceania: projection of heat supply by energy carrier – reference, energy [r]evolution, advanced energy [r]evolution scenarios 9,000 8,000 7,000 6,000

PJ/a

Biomass

5,000 4,000

EFFICIENCY

3,000

ELECTRIC HEATING

2,000

& HEAT PUMPS

HYDROGEN

GEOTHERMAL HEATING

SOLAR HEATING

1,000

BIOMASS FOSSIL

188

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

6.11.6 future investments in the heating sector

also in the heating sector the energy [r]evolution scenarios would require a major revision of current investment strategies in heating technologies. in particular, solar thermal, geothermal and heat pump technologies need an enormous increase in installations if these potentials are to be tapped for the heating sector. the use of biomass for heating purposes will shift from often traditional biomass today to modern, efficient and environmentally friendly heating technologies in the energy [r]evolution scenarios. renewable heating technologies are extremely variable, from low tech biomass stoves and unglazed solar collectors to very sophisticated enhanced geothermal and solar systems. thus, it can only be roughly estimated that the energy [r]evolution scenario in total requires around Us$ 720 billion to be invested in renewable heating technologies up to 2050 (including investments for replacement after the economic lifetime of the plants) - approximately Us$ 18 billion per year. the advanced scenario assumes an equally ambitious expansion of renewable technologies assuming a slightly higher share of direct electric heating, while the main strategy in the scenario is the substitution of the remaining natural gas amounts with electricity, hydrogen or other synthetic fuels.

table 6.11.3 | oecd asia oceania: installed capacities for renewable heat generation under the scenarios in gw

Biomass

ref e[r] adv

geotHermal

ref e[r] adv

solar Heating

ref e[r] adv

Heat PUmPs

ref e[r] adv

total*

ref e[r] adv

2012 40 40 40 0 0 0 9 9 9 5 5 5 53 53 53

2020 59 87 86 0 3 3 14 15 15 5 7 7 78 111 110

2030 69 130 130 0 8 8 25 151 151 5 28 28 100 317 317

2040 77 164 164 0 14 14 41 258 258 6 69 69 124 506 506

2050 87 164 122 0 24 25 62 277 280 6 94 95 155 560 522

* excluding direct electric heating.

figure 6.11.9 | oecd asia oceania: development of investments for renewable heat generation technologies â&#x20AC;&#x201C; reference, energy [r]evolution, advanced energy [r]evolution scenarios

ref 2012-2050

e[r] 2012-2050

HEAT PUMPS,

TOTAL

BIOMASS,

TOTAL

152 BILLION USD

720 BILLION USD SOLAR,

43%

BIOMASS,

49%

adv e[r] 2012-2050 22%

HEAT PUMPS,

27%

GEOTHERMAL,

SOLAR,

43%

BIOMASS,

TOTAL

700 BILLION USD

20%

HEAT PUMPS,

27%

GEOTHERMAL,

SOLAR,

45%

189

world energy [r]evolution a sustainable world energy outlook

6.11.7 future employment in the energy sector

the advanced Energy [R]evolution scenario results in more energy sector jobs in oECD asia oceania at every stage of the projection.

figure 6.11.10 | oecd asia oceania: employment in the energy sector under the reference and advanced energy [r]evolution

• there are 0.8 million energy sector jobs in the advanced energy [r]evolution in 2020, and 0.4 million in the reference scenario.

• in 2030, there are 1.1 million jobs in the advanced energy [r]evolution scenario and 0.4 million in the reference scenario. figure 6.11.4 shows the change in job numbers under both scenarios for each technology between 2015 and 2030. Jobs in the reference scenario drop to 10% below 2015 levels by 2020 and then remain quite stable to 2030.

1.0 Direct jobs - Millions

• in 2025, there are 1 million jobs in the advanced energy [r]evolution scenario, and 0.4 million in the reference scenario.

1.2

strong growth in renewable energy leads to an increase of 65% in total energy sector jobs in the advanced energy [r]evolution scenario by 2020. by 2030, energy jobs are more than double 2015 levels. renewable energy accounts for 80% at 2030, with pV having the greatest share (32%), followed by biomass, wind, and solar heating.

0.8

0.6

0.4

0.2

2015

2020

2025

2030

2020

REF GEOTHERMAL SOLAR

& HEAT PUMP

- HEAT

2030

ADV E[R] WIND HYDRO

OCEAN

BIOMASS

SOLAR THERMAL POWER

NUCLEAR

GEOTHERMAL POWER

GAS, OIL

COAL

table 6.11.4 | oecd asia oceania: total employment in the energy sector

2025

& DIESEL

in thousand jobs

advanced energy [r]evolution

reference

2015

2020

2025

2030

2020

2025

2030

90 59 134 177 459

81 63 135 140 419

88 70 133 147 439

88 74 133 147 442

52 50 145 509 756

41 45 144 735 965

24 43 140 820 1,027

190 37 135 93 5 459

128 17 158 105 11 419

127 17 160 115 19 439

115 12 162 127 27 442

371 99 176 105 4 756

467 141 233 122 2.3 965

477 149 276 124 0.8 1,027

jobs by fuel

coal gas, oil

diesel

nuclear renewables total jobs jobs by sector

construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs

190

energy

[r]evolution

6.11.8 transport table 6.11.5 | oecd asia oceania: projection of transport energy demand by mode in the reference and the energy [r]evolution scenarios in pj /a

a key target in oecd asia oceania is to introduce incentives for people to drive smaller cars and buy new, more efficient vehicle concepts. in addition, it is vital to shift transport use to efficient modes like rail, light rail and buses, especially in the expanding large metropolitan areas. along with rising prices for fossil fuels, these changes reduce the further growth in car sales projected under the reference scenario. despite population increase, gdP growth and higher living standards, energy demand from the transport sector is expected to decrease in the reference scenario by around 25% to 4,400 PJ/a in 2050. in the basic energy [r]evolution scenario, efficiency measures and modal shifts will save 40% (1,780 PJ/a) in 2050 compared to the reference scenario.

rail

ref e[r] adv

road

ref e[r] adv

domestic aviation ref e[r] adv

additional modal shifts and technology switches lead to even higher energy savings in the advanced scenario of 50% (2,180 PJ/a) in 2050 compared to the reference scenario. Highly efficient propulsion technology with hybrid, plug-in hybrid and battery-electric power trains will bring about large efficiency gains. By 2030, electricity will provide 12% of the transport sectorâ&#x20AC;&#x2122;s total energy demand in the energy [r]evolution, while in 2050 the share will be 45% (53% in the advanced scenario). Hydrogen and other synthetic fuels generated using renewable electricity are complementary options to further increase the renewable share in the transport sector. in 2050, up to 580 PJ/a of hydrogen is used in the transport sector for the advanced energy [r]evolution scenario.

domestic

ref

navigation

e[r] adv ref

total

e[r] adv

2012 149 149 149 5,203 5,203 5,203 254 254 254 203 203 203 5,808 5,808 5,808

2020 152 144 157 4,757 5,037 4,958 317 298 295 165 173 173 5,390 5,652 5,584

2030 152 132 191 4,538 3,784 3,449 325 258 245 160 151 151 5,175 4,325 4,036

2040 153 131 231 4,332 2,771 2,282 342 239 203 150 130 130 4,977 3,271 2,845

2050 154 138 285 3,755 2,150 1,650 338 221 172 140 110 110 4,387 2,619 2,217

figure 6.11.11 | oecd asia oceania: final energy consumption in transport under the scenarios

6,000

5,000

PJ/a

4,000

3,000 EFFICIENCY HYDROGEN

2,000

ELECTRICITY SYNFUELS

1,000

BIOFUELS NATURAL GAS OIL PRODUCTS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

191

world energy [r]evolution a sustainable world energy outlook

6.11.10 development of co 2 emissions

CO2 emissions [Mt/a]

With a 29% share of co 2, the industry sector will be the largest source of emissions in 2050 in the basic energy [r]evolution scenario. By 2050, oecd asia oceania´s co 2 emissions are around 95% below 1990 levels in the energy [r]evolution scenario while energy consumption is fully decarbonised in the advanced case.

Population (million)

2,500

250

2,000

200

1,500

150

1,000

100

500

6.11.11 primary energy consumption

taking into account the assumptions discussed above, the resulting primary energy consumption under the energy [r]evolution scenarios is shown in figure 6.11.12. Under the basic energy [r]evolution scenario, primary energy demand will decrease by 47% from today’s 35,800 PJ/a to around 19,000 PJ/a. compared to the reference scenario, overall primary energy demand will be reduced by 48% in 2050 under the energy [r]evolution scenario (reference scenario: around 36,000 PJ in 2050). the advanced scenario results due to additional conversion losses in a primary energy consumption of around 20,900 PJ in 2050.

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

SAVINGS

TRANSPORT

OTHER SECTORS

POWER GENERATION

INDUSTRY

POPULATION

expansion of renewable energies and a fast introduction of very efficient vehicle concepts in the transport sector to replace oil based combustion engines. this leads to an overall renewable primary energy share of 35% in 2030 and 81% in 2050 in the basic energy [r]evolution and of more than 89% in 2050 in the advanced case (incl. non-energy consumption). in contrast to the reference scenario, no new nuclear power plants will be built in oecd asia oceania in the energy [r]evolution scenarios.

the energy [r]evolution scenarios aim to phase out coal and oil as fast as technically and economically possible by

figure 6.11.12 | oecd asia oceania: projection of total primary energy demand (ped) by energy carrier including electricity import balance – reference , energy [ r ] evolution , advanced energy [ r ] evolution scenarios 40,000 35,000 30,000

EFFICIENCY OCEAN ENERGY

25,000 PJ/a

figure 6.11.13 | oecd asia oceania: development of co2 emissions by sector under the energy [r]evolution scenarios ‘savings ’ = reduction compared to the reference scenario

Whilst oecd asia oceania’s emissions of co 2 will decrease by 22% between 2012 and 2050 under the reference scenario, under the energy [r]evolution scenario they will decrease from 2,210 million tonnes in 2012 to 85 million tonnes in 2050. annual per capita emissions will drop from 10.9 tonne to 0.4 tonne. in spite of the abstinence of nuclear power production and increasing power demand, co 2 emissions will decrease in the electricity sector. in the long run efficiency gains and the increased use of renewable electricity in vehicles strongly reduce emissions in the transport sector as well.

GEOTHERMAL SOLAR

20,000

BIOMASS WIND

15,000

HYDRO NATURAL GAS

10,000

CRUDE OIL COAL

5,000

NUCLEAR NET ELECTRICITY IMPORTS

192

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

table 6.11.6 | oecd asia oceania: accumulated investment costs for electricity generation and fuel cost savings under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

183.8 -220.5 -36.7

309.8 -589.4 -279.5

338.1 -408.5 -70.4

311.6 -588.7 -277.1

1,143.3 -1,807.1 -663.8

29.3 -46.3 -17.0

$ $ $ $ $ $

-31.2 -12.3 24.3 1.6 11.4 -6.2

-40.5 119.3 111.2 11.1 65.3 266.4

22.9 346.8 225.3 23.6 96.7 715.3

39.5 731.6 273.9 28.7 119.2 1,192.8

-9.4 1,185.4 634.7 65.0 292.6 2,168.3

-0.2 30.4 16.3 1.7 7.5 55.6

average per year nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.11.7 | oecd asia oceania: accumulated investment costs for renewable heat generation under the energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

28.5

179.8

192.8

163.5

564.5

2012 - 2050 average per year

14.5

table 6.11.8 | oecd asia oceania: accumulated investment costs for electricity generation and fuel cost savings under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

conventional (fossil

Billion

difference ref minUs advanced e[r]

reneWaBles

+ (incl. cHP)

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

2012 - 2050

$ $ $

185.7 -285.1 -99.4

332.2 -796.4 -464.3

350.9 -659.1 -308.1

269.1 -887.1 -618.0

1,137.8 -2,627.6 -1,489.8

29.2 -67.4 -38.2

$ $ $ $ $ $

-31.2 -8.6 20.8 1.6 11.4 -6.1

-40.5 137.7 126.6 11.1 65.3 300.2

22.9 403.5 239.9 23.6 96.7 786.6

45.9 849.0 275.5 28.7 119.2 1,318.3

-2.9 1,381.6 662.7 65.0 292.6 2,398.9

-0.1 35.4 17.0 1.7 7.5 61.5

average per year

nUclear)

Billion Billion

total accumulated fuel cost savings

savings cUmUlative advanced e[r] versUs ref

fUel oil

Billion

gas

Billion

Hard coal

Billion

lignite

Billion

nUclear energy

Billion

total

Billion

table 6.11.9 | oecd asia oceania: accumulated investment costs for renewable heat generation under the advanced energy [r]evolution scenario compared to the reference scenario

accumulated investment costs

unit

reneWaBles

Billion

difference ref minUs advanced e[r]

2012-2020

2021-2030

2031-2040

2041-2050

2012-2050

28.3

179.9

192.6

148.3

549.2

2012 - 2050 average per year

14.1

193

e m p loy m e n t p r o j e ct i o n s m e t h o d o lo gy a n d a s s u m p t i o n s employment factors

regional adjustments

7 â&#x20AC;&#x153;

just transition: investment in education rather than fossil fuelsâ&#x20AC;?

ÂŠ nasa earth observatory image by jesse allen

image hundreds of salt lakes are sprinkled across the landscape of northern and western australia. most, including lake mackay, fill infrequently via seasonal rainfall that runs off of nearby lands and through minor drainage channels. water can persist in lake mackay for at least six months after a flood; when it does, the ephemeral lake provides an important habitat and breeding area for shorebirds and waterbirds

194

energy

[r]evolution

the institute for sustainable futures at the University of technology sydney modelled the effects of the reference scenario and advanced energy {r]evolution scenario on jobs in the energy sector. this section provides a simplified overview of how the calculations were performed. a detailed methodology is also available. 1 chapters 6 and 7 contain all the data on how the scenarios were developed. the main inputs to the calculations are: for each scenario, namely the reference (business as usual) and advanced energy [r]evolution scenario: • the amount of electrical and heating capacity that will be installed each year for each technology. • the primary energy demand for coal, gas, and biomass fuels in the electricity and heating sectors. • the amount of electricity generated per year from nuclear, oil, and diesel. for each technology: • employment factors’, or the number of jobs per unit of capacity, separated into manufacturing, construction, operation and maintenance, and per unit of primary energy for fuel supply.

• for the 2020, 2025, and 2030 calculations, a ‘decline factor’ for each technology which reduces the employment factors by a certain percentage per year. this reflects the fact that employment per unit falls as technology efficiencies improve. for each region: • the percentage of local manufacturing and domestic fuel production in each region, in order to calculate the proportion of manufacturing and fuel production jobs which occur in the region. • the percentage of world trade which originates in each region for coal and gas fuels, and renewable traded components. • a “regional job multiplier”, which indicates how labourintensive economic activity is in that region compared to the oecd. this is used to adjust oecd employment factors where local data is not available. the electrical capacity increase and energy use figures from each scenario are multiplied by the employment factors for each of the technologies, and then adjusted for regional labour intensity and the proportion of fuel or manufacturing which occurs locally. the calculation is summarised in the figure 7.1.

figure 7.1 | methodology overview

manufacturing local use )

mw installed per year in region

manufacturing employment factor

regional job multiplier for year

manufacturing (for export)

mw exported per year

manufacturing employment factor

regional job multiplier for year

construction

mw installed per year

construction employment factor

regional job multiplier for year

operation and maintenance

cumulative capacity

employment factor

regional job multiplier for year

fuel supply (nuclear)

electricity generation

fuel employment factor

regional job multiplier for year

fuel supply ( coal , gas and biomass )

primary energy demand plus exports

fuel employment factor ( always regional for coal )

regional job multiplier for year

heat supply

mw installed per year

employment factor for heat

regional job multiplier for year

jobs in region

manufacturing

construction

operation and maintenance (o&m)

employment factors at 2020 or 2030

(for

2015

employment factor

o&m

technology decline factor

% local manufacturing

of local production

fuel

heat

[number of years after 2015]

references 1

rUtovitz, J., dominisH, e. and doWnes, J. 2015. calcUlating gloBal energy sector JoBs: 2015 metHodology UPdate. PrePared for greenPeace international By tHe institUte for sUstainaBle fUtUres, University of tecHnology sydney.

195

world energy [r]evolution a sustainable world energy outlook

a range of data sources are used for the model inputs, including the international energy agency, Us energy information administration, BP statistical review of World energy, Us national renewable energy laboratory, international labour organisation, World Bank, industry associations, national statistics, company reports, academic literature, and isf’s own research.

these calculations only take into account direct employment, for example the construction team needed to build a new wind farm. they do not cover indirect employment, for example the extra services provided in a town to accommodate the construction team. the calculations do not include jobs in energy efficiency, although these are likely to be substantial, as the energy [r]evolution leads to a 34% drop in primary energy demand in the heating and electricity sectors at 2030. the large number of assumptions required to make calculations mean that employment numbers are indicative only, especially for regions where little data exists. However, within the limits of data availability, the figures presented are representative of employment levels under the two scenarios.

7.1 employment factors “employment factors” are used to calculate how many jobs are required per unit of electrical or heating capacity, or per unit of fuel. they take into account jobs in manufacturing, construction, operation and maintenance and fuel. table 7.1 lists the employment factors used in the calculations. these factors are usually from oecd countries, as this is where there is most data, although local factors are used wherever possible. for job calculations in non oecd regions, a regional adjustment is used where a local factor is not available. employment factors were derived for every region for coal supply, because coal is currently so dominant in the global energy supply, and because employment per tonne varies so much by region. in australia and the Us coal is extracted at an average of more than 8,000 tonnes 3 per person per year, while in europe the average coal miner is responsible for less than 1,000 tonnes per year. india, china, and eastern europe/eurasia have relatively low productivity at present, with 600-700 tonnes per worker per year, but annual increases in productivity are very high. the projections in coal mining employment take into account the trend in

table 7.1 | summary of employment factors used in global analysis 2015 construction / installation

manufacturing

operations

JoB years / mW

maintenance JoBs / mW

coal

11.2

5.4

0.14

regional

gas

1.3

0.93

0.14

regional

nUclear

11.8

1.3

0.6

0.001 JoBs / gWh final energy demand

Biomass

14.0

2.9

1.5

29.9

Hydro-large

7.4

3.5

0.2

Hydro-small

15.8

10.9

4.9

Wind onsHore

3.2

4.7

0.3

Wind offsHore

8.0

15.6

0.2

13.0

6.7

0.7

geotHermal

11.2

5.4

0.4

solar tHermal

1.3

0.93

0.6

ocean

10.2

0.6

geotHermal solar

Heat

nUclear decommissioning

6.9 JoBs/mW (constrUction & manUfactUring) 8.4 JoBs/mW (constrUction & manUfactUring) 0.95

JoBs Per mW decommissioned

comBined Heat and PoWer cHP tecHnologies Use tHe factor for tHe tecHnology, i.e. coal, gas, Biomass, geotHermal, etc, increased By a factor of 1.5 for o&m only. note for details of sources and derivation of factors see rutovitz et al, 2015.2

references 2

196

fuel

–

primary energy demand

JoBs

energy

[r]evolution

productivity in india, china, and russia. data for the the last 7 to 15 years were used to calculate an annual improvement trend, which has been used to derive an annual percentage reduction in the employment factors for coal mining over the study period. local data is also used for gas extraction for every region except india, the middle east and other (non-oecd) asia. the calculation of coal and gas employment per PJ draws on data from national statistics and company reports, combined with production figures from the BP statistical review of World energy 2015 4 or other sources. data was collected for as many major coal producing countries as possible,with coverage obtained for 90% of world coal production

7.2 regional adjustments 7.2.1 regional job multipliers

the employment factors used in this model for energy technologies other than coal mining are most often for oecd regions, which are typically wealthier. a regional multiplier is applied to make the jobs per mW more realistic for other parts of the world. in developing countries it typically means more jobs per unit of electricity because those countries have more labour intensive practices. the multipliers change over the study period in line with the projections for gdP per worker. this reflects the fact that as prosperity increases, labour intensity tends to fall. the multipliers are shown in table 7.3. 7.2.2 local employment factors

local employment factors are used where possible. region specific factors are: • oecd north america: gas and coal fuel, Pv and offshore wind (all factors), and solar thermal power (construction and o&m).

table 7.3 | regional multipliers 2015

2020

2030

• other europe: gas and coal fuel, offshore wind (all factors), solar thermal power (construction and o&m), and solar heating.

oecd

1.0

• oecd asia oceania: gas and coal fuel.

africa

5.7

5.4

4.5

2.6

2.1

1.5

• africa: gas, coal and biomass fuel.

cHina otHer (non-oecd) asia

2.4

2.3

1.9

eastern eUroPe/eUrasia

6.0

5.0

3.6

• eastern europe/eurasia: gas and coal fuel.

india

6.9

5.9

3.8

3.4

3.3

2.9

• other (non-oecd) asia: coal fuel.

latin america middle east

1.4

1.2

source derived from ilo (2013) Key indicators of the labour market, eighth edition software, with growth in gdP per capita derived from iea World energy outlook 2014 and World Bank data.

• china: gas and coal fuel, and solar heating.

• india: coal fuel, and solar heating. • latin america: coal and biomass fuels, onshore wind (all factors), nuclear (construction and o&m), large hydro (o&m) and small hydro (construction and o&m).

table 7.2 | employment factors used for coal fuel supply (mining and associated jobs) employment factor JoBs Per

tonnes per person per year

average yearly productivity

(coal

increase

eqUivalent )

2015 - 2030

oecd nortH america

3.8

8,900

not calcUlated

oecd asia oceania

4.1

8,380

not calcUlated

otHer (non-oecd) asia

6.1

5,600

not calcUlated

africa

14.4

2,370

not calcUlated

latin america

15.4

2,200

not calcUlated

world average

39.0

875

not calculated

oecd eUroPe

40.1

850

not calcUlated

india

48.3

700

eastern eUroPe/eUrasia

51.1

670

10%

cHina

56.1

600

middle east

Used World average of

39.7,

as no emPloyment data availaBle

references 4

BP statistical revieW of World energy 2015.

197

world energy [r]evolution a sustainable world energy outlook

local manufacturing and fuel production

learning adjustments or â&#x20AC;&#x2DC;decline factorsâ&#x20AC;&#x2122;

some regions do not manufacture the equipment needed for installation of renewable technologies, for example wind turbines or solar Pv panels. the model takes into account a projection of the percentage of renewable technology which is made locally. the jobs in manufacturing components for export are counted in the region where they originate. the same applies to coal and gas fuels, because they are traded internationally, so the model shows the region where the jobs are actually located.

these account for the projected reduction in the cost of renewable over time, as technologies and companies become more efficient and production processes are scaled up. generally, jobs per mW would fall in parallel with this trend. the cost projections for each region in the energy [r]evolution scenarios have been used to derive these factors.

198

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[r]evolution

7.3 employment results by technology

employment in gas, oil & diesel

7.3.1 employment in fossil fuels and nuclear energy

employment in the gas, oil and diesel sectors increases by 12% in the reference scenario, despite corresponding generation in gas, oil and diesel increasing by 29%. this reflects increasing efficiencies in the sector. in the advanced energy [r]evolution scenario, employment and generation remains relatively stable, just above 2015 levels. gas sector jobs in both scenarios include heat supply jobs from gas.

employment in coal

Jobs in the coal sector drop significantly in both the reference scenario and the advanced energy [r]evolution scenario. in the reference scenario coal employment drops by 2 million jobs between 2020 and 2030, despite generation from coal nearly doubling. coal employment in 2015 was close to 9.8 million, so this is in addition to a loss of 0.1 million jobs from 2015 to 2020. this is because employment per ton in coal mining is falling dramatically as efficiencies increase around the world. for example, one worker in the new chinese â&#x20AC;&#x2DC;super minesâ&#x20AC;&#x2122; is expected to produce 30,000 tonnes of coal per year, compared to current average productivity across all mines in china of about 600 tonnes per year, and average productivity per worker in north america of close to 9,000 tonnes. Unsurprisingly, employment in the coal sector in the advanced energy [r]evolution scenario falls even more between 2020 and 2030, reflecting reduction in coal generation from 34% to 16% of all generation, on top of the increase in efficiency.

employment in nuclear energy

employment in nuclear energy falls by 15% in the reference scenario between 2020 and 2030, while generation increases by 14%. in the advanced energy [r]evolution generation is reduced by 70% between 2020 and 2030, representing a virtual phase out of nuclear power. employment in the energy [r]evolution scenario increases slightly, and in 2020 and 2030 is very similar in both scenarios. this is because jobs in nuclear decommissioning replace jobs in generation. it is expected these jobs will persist for 20 - 30 years.

coal jobs in both scenarios include coal used for heat supply.

table 7.4 | fossil fuels and nuclear energy: capacity and direct jobs adv e [ r ] scenario

reference scenario

employment in the energy sector fossil fuels and nuclear

coal gas, oil

diesel

nUclear energy

Unit

2015

2020

2025

2030

2020

2025

2030

tHoUsands tHoUsands

9,757 3,581 734

9,671 4,163 865

8,634 4,564 828

7,704 4,667 739

4,799 4,002 523

3,279 4,176 519

1,966 3,978 507

gW tWH %

1,911 9,732 39%

2,164 11,086 39%

2,460 12,676 39%

2,756 14,266 39%

1,854 9,450 34%

1,584 8,058 26%

1,248 5,873 16%

-46

-51

gW tWH %

1,990 6,528 26%

2,227 6,993 25%

2,442 8,004 25%

2,655 9,016 25%

2,158 7,228 26%

2,269 7,329 23%

2,324 7,089 19%

28,019

gW tWH %

414 2,744 11%

447 3,215 11%

471 3,443 11%

496 3,670 10%

260 1,872 7%

184 1,345 4%

76 559 2%

8.3

6.0

5.7

-21

-12

-10

tHoUsands

coal

energy installed caPacity total generation sHare of total sUPPly market annUal increase in caPacity gas , oil

diesel

energy installed caPacity total generation sHare of total sUPPly market annUal increase in caPacity nuclear energy

energy installed caPacity total generation sHare of total sUPPly market annUal increase in caPacity

199

world energy [r]evolution a sustainable world energy outlook

7.3.2 employment in wind energy and biomass

employment in biomass

employment in wind energy

in the advanced energy [r]evolution scenario, biomass provides 5.4% of total electricity generation by 2030, and employs 11.5 million people. in the reference scenario, biomass provides a smaller share of electricity, (2.9%), but employs 11.8 million people, sllightly more than in the advanced energy [r]evolution scenario. Jobs in heating from biomass fuels are also included here.

in the advaced energy [r]evolution scenario, wind energy provides 21% of total electricity generation by 2030, and employs 8.2 million people. growth is much more modest in the reference scenario, with wind energy providing 5% of generation, and employing only 0.6 million people.

7 table 7.5 | windpower: capacity and direct jobs adv e [ r ] scenario

reference scenario

Wind

Unit

2015

2020

2025

2030

2020

2025

2030

gW tWH % gW

380 794 3% -

554 1,254 4% 41

681 1,608 5% 29

807 1,962 5% 28

904 2,158 8% 158

1,873 4,645 15% 280

3,064 7,737 21% 302

tHoUsand

697

720

760

650

4,218

6,906

8,181

energy installed caPacity total generation sHare of total sUPPly annUal increase in caPacity employment in the energy sector direct JoBs in constrUction, manUfactUre, oPeration and maintenance

table 7.6 | biomass: capacity and direct jobs adv e [ r ] scenario

reference scenario

Biomass

Unit

2015

2020

2025

2030

2020

2025

2030

gW tWH % gW

119 554 2.2% 0.0

150 740 2.6% 7.1

174 890 2.7% 5.4

199 1 039 2.9% 5.3

200 979 3.5% 31.8

295 1,505 4.8% 26.7

405 1,993 5.4% 26.2

tHoUsand

10,970

11,850

12,052

11,762

12,068

12,553

11,544

energy installed caPacity total generation sHare of total sUPPly annUal increase in caPacity employment in the energy sector direct JoBs in constrUction, manUfactUre, oPeration and maintenance

200

energy

[r]evolution

7.3.3 employment in geothermal and wave power

employment in wave and tidal power

employment in geothermal power

in the advanced energy [r]evolution scenario, wave and tidal power would provide 1% of total electricity generation by 2030, and would employ 652 thousand people. Growth is much more modest in the reference scenario, with wave and tidal power providing less than 0.1% of generation, and employing only 14 thousand people.

in the advanced energy [r]evolution scenario, geothermal power would provide 2% of total electricity generation by 2030, and would employ 386 thousand people. Growth is much more modest in the reference scenario, with geothermal power providing less than 1% of generation, and employing only 34 thousand people.

7 table 7.7 | geothermal: capacity and direct jobs adv e [ r ] scenario

reference scenario

Geothermal

unit

2015

2020

2025

2030

2020

2025

2030

GW tWh % GW

14 93 0.4% -

17 113 0.4% 0.7

22 151 0.5% 1.2

28 188 0.5% 1.2

31 210 0.7% 7

85 558 1.5% 19

171 1,149 2.5% 24

thousand

32.2

34.0

181

305

386

energy installed capacity total Generation share of total supply annual increase in capacity employment in the energy sector direct jobs in construction, manufacture, operation and maintenance

table 7.8 | wave and tidal power: capacity and direct jobs adv e [ r ] scenario

reference scenario

Wave and tidal poWer

unit

2015

2020

2025

2030

2020

2025

2030

GW tWh % GW

0.6 1.4 0.0% 0.0

1.1 2.9 0.0%

2.3 6.4 0.0% 0.4

3.6 10 0.027% 0.3

11.4 32 0.1% 4.1

46 128 0.4%

131 363 1.0% 26.4

thousand

1.6

232

energy installed capacity total Generation share of total supply annual increase in capacity

0.1

employment in the energy sector direct jobs in construction, manufacture, operation and maintenance

10.2 449

652

201

world energy [r]evolution a sustainable world energy outlook

7.3.4 employment in solar photovoltaics and solar thermal power employment in solar photovoltaics

in the advanced energy [r]evolution scenario, solar photovoltaic would provide 14% of total electricity generation by 2030, and would employ 10.3 million people. Growth is much more modest in the reference scenario, with solar photovoltaic providing less than 2% of generation, and employing only 0.7 million people.

employment in solar thermal power

in the advanced energy [r]evolution scenario, solar thermal power would provide 7% of total electricity generation by 2030, and would employ 2.7 million people. Growth is much lower in the reference scenario, with solar thermal power providing only 0.2% of generation, and employing only 80 thousand people.

7 table 7.9 | solar photovoltaics: capacity and direct jobs adv e [ r ] scenario

reference scenario

solar photovoltaics

unit

2015

2020

2025

2030

2020

2025

2030

GW tWh % GW

186 214 0.9% -

332 408 1.4% 38.0

413 519 1.6% 18.6

494 630 1.7% 17.8

844 1,090 3.9% 232

2,000 2,659 8.5% 326

3,725 5,067 13.7% 447

thousand

1,015

870

839

661

6,690

11,042

10,322

energy installed capacity total Generation share of total supply annual increase in capacity employment in the energy sector direct jobs in construction, manufacture, operation and maintenance

table 7.10 | solar thermal power: capacity and direct jobs adv e [ r ] scenario

reference scenario

solar thermal poWer

unit

2015

2020

2025

2030

2020

2025

2030

GW tWh % GW

6 13 0.1% 0.0

11 34 0.1% 1.5

19 60 0.2% 1.9

26 85 0.2% 1.7

42 131 0.5% 14.9

177 608 2% 52

635 2,552 7% 151

thousand

450

1,664

2,659

energy installed capacity total Generation share of total supply annual increase in capacity employment in the energy sector direct jobs in construction, manufacture, operation and maintenance

202

energy

[r]evolution

7.3.5 employment in the renewable heating sector

employment in geothermal and heat pump heating

employment in the renewable heating sector

in the advanced energy [r]evolution scenario, geothermal and heat pump heating would provide 7% of total heat supply by 2030, and would employ 1.5 million people. Growth is much more modest in the reference scenario, with geothermal and heat pump heating providing less than 1% of heat supply, and employing only 37 thousand people.

employment in the renewable heat sector includes jobs in installation, manufacturing, and fuel supply. this analysis includes only jobs associated with fuel supply in the biomass sector, and jobs in installation and manufacturing for direct heat from solar, geothermal and heat pumps. it is therefore likely to be an underestimate of jobs in this sector.

employment in biomass heat employment in solar heating

in the advanced energy [r]evolution scenario, solar heating would provide 9% of total heat supply by 2030, and would employ 5.6 million people. Growth is much more modest in the reference scenario, with solar heating providing just over 1% of heat suuply, and employing only 0.3 million people.

in the advanced energy [r]evolution scenario, biomass heat would provide 24% of total heat supply by 2030, and would employ 5.5 million people. Growth is slightly less in the reference scenario, with biomass heat providing 18% of heat supply, and employing 5.1 million people.

table 7.11 | solar heating: capacity and direct jobs adv e [ r ] scenario

reference scenario

solar heatinG

unit

2015

2020

2025

2030

2020

2025

2030

GW pj % GW

296 1,019 0.7% 20.5

401 1,386 0.9% 21

503 1,746 1.0% 20

604 2,107 1.2% 20

749 2,676 1.8% 86

1,863 6,994 5% 223

3,421 12,994 9% 312

thousand

363

373

337

312

1,592

3,940

5,637

energy installed capacity heat supplied share of total heat supply annual increase in capacity employment in the energy sector direct jobs in installation and manufacture

table 7.12 | geothermal and heat pump heating: capacity and direct jobs adv e [ r ] scenario

reference scenario

Geothermal and heat pump heatinG

unit

2015

2020

2025

2030

2020

2025

2030

GW pj % GW

100 565 0.4% 5.0

123 689 0.4% 4.5

144 810 0.5% 4.4

166 929 0.5% 4.3

281 2,134 1.4% 34.4

680 5,197 3% 80

1,286 10,417 7% 121

thousand

476

992

1,465

energy installed capacity heat supplied share of total heat supply annual increase in capacity employment in the energy sector direct jobs in installation and manufacture

table 7.13 | biomass heat: direct jobs in fuel supply e [ r ] scenario

reference scenario

biomass heat

unit

2015

2020

2025

2030

2020

2025

2030

pj %

28,407 19%

29,818 19%

31,115 18%

32,467 18%

31,404 21%

34,909 23%

36,623 24%

thousand

5,150

5,372

5,351

5,136

5,699

5,965

5,487

energy heat supplied share of total heat supply employment in the energy sector direct jobs in fuel supply

203

t h e s i l e n t e n e r gy m a r k e t [ r ] e vo lu t i o n the power plant market 1970 to 2014

the global market shares in the power plant market: renewables gaining ground

the first decade: the development of the renewable power plant market

the global renewable energy market in 2014

“

renewables gained the largest market share in 2014”

image tunisia’s second largest city, sfax. sfax is a major port and home to tunisia’s largest fishing fleet. the most recognizable features of sfax from space are the brilliantly colored salt ponds south of the old city and the new circular earth works of the taparura redevelopment project just to the north.

204

energy

[r]evolution

the next few years without good renewable energy policies – especially in regard to priority grid access and dispatching and legally binding co 2 reduction targets.

8.1 the power plant market 1970 to 2011 an analysis of the global power plant market of the past 45 years shows that since the late 1990s, wind and solar installations grew faster than any other power plant technology across the world - about 533,000 mW total capacity between 2000 and 2014. including all other renewable power technologies (hydro, biomass, concentrated solar and geothermal), a total of 894,000 mW of new capacity has been connected to the grid. however, it is too early to claim the end of the fossil fuel based power generation, because during the same timeframe, almost the same amount of new coal power plants – approx. 840,000 mW – were built with embedded cumulative emissions of around 100 billion tonnes co 2 over their technical lifetime.

between 1970 and 1990, the global power plant market in the oecd 2 was dominated by countries that electrified their economies mainly with coal, gas and hydro power plants. the power sector was largely in the hands of state-owned and investor owned utilities with regional or nationwide supply monopolies. the nuclear industry had a relatively short period of steady growth between 1970 and the mid-1980s - with a peak in 1985, one year before the chernobyl accident - and went into decline in following years, with no signs of growth since then. between 1990 and 2000, the global power plant industry went through a series of changes. While oecd countries began to liberalise their electricity markets, electricity demand did not match previous growth, so fewer new power plants were built. capital-intensive projects with long payback times, such as coal and nuclear power plants, were unable to get sufficient financial support. it was the decade of gas power plants.

the global market volume of renewable energy in 2014 was, for the first time ever, higher than the global net addition of fossil fuel capacity (ren21-2015). 1 there is a window of opportunity for new renewable energy installations to replace old plants in oecd countries and for electrification in developing countries. however, the window will close within

figure 8.1 | global annual power plant market 1970 - 2014

300,000

250,000

MW/a

200,000

150,000

100,000

50,000

n n n n

nuclear poWer plants coal poWer plants oil poWer plants

n n n

biomass Geothermal hydro

n n n

2014

2013

2012

2011

2010

2009

2008

2007

2006

2005

2004

2003

2002

2001

2000

1999

1998

1997

1996

1995

1994

1993

1992

1991

1990

1989

1988

1987

1986

1985

1984

1983

1982

1981

1980

1979

1978

1977

1976

1975

1974

1973

1972

1971

1970

Wind concentrated solar poWer solar photovoltaic

Gas poWer plants (incl. oil)

source platts, ren21, eWea, GWec, epia, national statistics, iea, breyer. data compilation dr. sven teske/Greenpeace.

references 1 2

(ren21 – 2015); reneWables 2015 -Global status report; annual reportinG on reneWables: ten years of excellence; ren21; c/o unep; 15, rue de milan, f-75441 paris cedex 09, france; june 2015; WWW.ren21.net. (oecd): orGanisation for economic co-operation and development.

205

world energy [r]evolution a sustainable world energy outlook

2014 were built in china. in 2014, the first signs that the end of aggressive coal expansion might end appeared: the national bureau of statics of china (nbsc 2015) 3 revealed that the thermal power generation in the first quarter of 2015 was down 3.7%, hydropower generation up 17% and “other” power generation (mainly wind, solar and nuclear) was up 18% on year. total energy consumption only grew 1% and total electricity consumption was stable. furthermore, gasfired capacity grew by 20% during 2014, and coal-power generation fell more than 4%; the overall coal consumption for the power sector declined by as much as 5%.

the economies of developing countries, especially in asia, started growing during the 1990s, triggering a new wave of power plant projects. similarly to the us and europe, most of the new markets in the ‘tiger states’ of southeast asia partly deregulated their power sectors. a large number of new power plants in this region were built by independent power producer (ipps), who sell the electricity mainly to stateowned utilities. the majority of new power plant technology in liberalised power markets is fuelled by gas except in china, which focused on building new coal power plants. about 75% of all new coal power plants worldwide between 2000 and

figure 8.2 | global annual power plant market – excluding china: 1970 - 2014

200,000 180,000 160,000 140,000

MW/a

120,000 100,000 80,000 60,000 40,000 20,000

n n n n

nuclear poWer plants coal poWer plants oil poWer plants

n n n

(nbsc 2015);press release from 15th april 2015; http://WWW.stats.Gov.cn/enGlish/pressrelease/201504/t20150415_712435.html

206

hydro

n n n

Wind concentrated solar poWer solar photovoltaic

2014

2013

2012

2011

2010

2009

2008

2007

2006

2005

2004

2003

2002

2001

2000

1999

1998

1997

1996

1995

1994

1993

1992

1991

1990

1989

1988

Geothermal

source platts, ren21, eWea, GWec, epia, national statistics, iea, breyer. data compilation dr. sven teske/Greenpeace.

1987

biomass

Gas poWer plants (incl. oil)

references

1986

1985

1984

1983

1982

1981

1980

1979

1978

1977

1976

1975

1974

1973

1972

1971

1970

energy

[r]evolution

Production Tax Credit (ptc) during the past years. the federal renewable electricity production tax credit (ptc) is a per-kWh tax credit for electricity generated by qualified energy resources and sold by the taxpayer to an unrelated person during the taxable year. originally enacted in 1992, the ptc has been changed numerous times, most recently in january 2013 (usa – energy.gov 2015). 4

8.1.1 power plant markets in the us, europe and china

the graphs show how much electricity market liberalisation influences the choice of power plant technology. While the us and european power sectors moved towards deregulated markets, which favour mainly gas power plants and increasingly onshore wind, china added large quantities of power generation capacities of various technologies. besides coal, there was a double digit GW market volume (over 10,000 mW of new capacity per year) for wind and hydro and – since 2013 – solar photovoltaics as well. china was the largest market for pv installations in 2013 and 2014 with no signs of decline in the near future.

the impact of the ptc on the usa wind market is significant. the united states ranked third for global wind market additions (nearly 4.9 GW), second for cumulative capacity at year’s end (65.9 GW), and first for wind power generation (181.8 tWh) during 2014. the us market rebounded with a record 13 GW under construction as of early 2015. texas led for capacity added (more than 1.8 GW), followed by oklahoma, iowa, Washington, and colorado. the federal ptc, which expired at the end of 2013, was reinstated retroactively in mid-december 2014. the solar photovoltaic market grows mainly due because grid parity has been reached. net-metering and gird connection regulations are of vital importance for future solar growth.

Us: liberalisation of the us power sector started with the energy policy act 1992 and became a game changer for the whole sector. in 2015, the us in is still far away from a fully liberalised electricity market, but the effect has been a shift from coal and nuclear towards gas and wind, with a slowly but steadily growing solar photovoltaic market. the economic backbone of the growing onshore wind market has been the

figure 8.3 | usa annual power plant market: 1970 - 2014

70,000 ENERGY POLICY ACT 1992

LIBERALISATION OF USA’S POWER MARKET

60,000

50,000

MW/a

40,000

30,000

20,000

10,000

n n n n

nuclear poWer plants coal poWer plants oil poWer plants

n n n

biomass Geothermal hydro

n n n

2014

2013

2012

2011

2010

2009

2008

2007

2006

2005

2004

2003

2002

2001

2000

1999

1998

1997

1996

1995

1994

1993

1992

1991

1990

1989

1988

1987

1986

1985

1984

1983

1982

1981

1980

1979

1978

1977

1976

1975

1974

1973

1972

1971

1970

Wind concentrated solar poWer solar photovoltaic

Gas poWer plants (incl. oil)

source platts, ren21, eWea, GWec, epia, national statistics, iea, breyer. data compilation dr. sven teske/Greenpeace.

references 4

(usa – enerGy.Gov 2015): official information from the Website of the us Government: http://enerGy.Gov/savinGs/reneWable-electricity-production-tax-credit-ptc

207

world energy [r]evolution a sustainable world energy outlook

in europe needed re-powering. in 1997, the eu established a renewable energy target of 20% by 2020. by mid-2015, it had become clear that this target will be most likely reached and that further energy policy changes – especially for infrastructure – are required. europe´s grid infrastructure and many power plants are ageing, and major investment decisions are being taken. in october 2014, eu leaders agreed on rather low renewable energy and energy efficiency targets for 2030. the target for a minimum 27 per cent share of renewables across europe ignores the potential for renewables to supply almost half of europe’s energy by 2030 and might have a negative impact of the future renewable power market in europe.

europe: about five years after the us began deregulating the power sector, the european community started a similar process with similar effect on the power plant market. investors backed fewer new power plants and extended the lifetime of the existing ones. new coal and nuclear power plants have had a market share of well below 10% for new projects since then. the growing share of renewables, especially wind and solar photovoltaics, is due to a legally binding target and the associated feed-in laws in force in many member states of the european community since the late 1990s. overall, new installed power plant capacity jumped to a record high because the aged power plant fleet

figure 8.4 | eu annual power plant market: 1970 - 2014

70,000 ENERGY POLICY ACT 1997

LIBERALISATION OF EU’S POWER MARKET

60,000

50,000

MW/a

40,000

30,000

20,000

10,000

n n n n

nuclear poWer plants coal poWer plants oil poWer plants

n n n

Geothermal hydro

Gas poWer plants (incl. oil)

n n n

Wind concentrated solar poWer solar photovoltaic

2014

2013

2012

2011

2010

2009

2008

2007

2006

2005

2004

2003

2002

2001

2000

1999

1998

1997

1996

1995

1994

1993

1992

1991

1990

1989

1988

1987

biomass

source platts, ren21, eWea, GWec, epia, national statistics, iea, breyer. data compilation dr. sven teske/Greenpeace.

208

1986

1985

1984

1983

1982

1981

1980

1979

1978

1977

1976

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1974

1973

1972

1971

1970

energy

[r]evolution

the global wind market. the chinese wind market declined to 12,960 mW in 2012 and increased again to 23,200 mW in 2014. hydro power plants maintain a large market share for new installations: around 150,000 mW of new capacity has been added, increasing the total installed capacity for hydro to 280,000 mW in china. solar photovoltaic is starting to play an increasing role with regard to newly installed capacity; 10,600 mW was added in 2014 alone; since 2011, china has added the same capacity of pv as Germany â&#x20AC;&#x201C; the world leader â&#x20AC;&#x201C; since 1994. future expansion of renewables depends especially on grid regulation as access to the power grid is the economic basis for renewables.

china: the steady economic growth in china since the late

1990s and the growing power demand led to an explosion of the coal power plant market, especially after 2002. in 2013, the market hit a new peak year for new coal power plants: 75% of new coal power plants built worldwide since 2000 were in china. at the same time, china is trying to take its dirtiest plants offline; between 2006 and 2010, a total of 76,825 mW of small coal power plants were phased out under the 11th five year programme. While coal still dominates new added capacity, wind power is rapidly growing as well. starting in 2003, the wind market doubled each year to over 18,000 mW 5 by 2010, constituting 49% of

figure 8.5 | china annual power plant market: 1970 - 2014

120,000 110,000 100,000 90,000 80,000

MW/a

70,000 60,000 50,000 40,000 30,000 20,000 10,000

n n n n

nuclear poWer plants coal poWer plants oil poWer plants

n n n

biomass Geothermal hydro

n n n

2014

2013

2012

2011

2010

2009

2008

2007

2006

2005

2004

2003

2002

2001

2000

1999

1998

1997

1996

1995

1994

1993

1992

1991

1990

1989

1988

1987

1986

1985

1984

1983

1982

1981

1980

1979

1978

1977

1976

1975

1974

1973

1972

1971

1970

Wind concentrated solar poWer solar photovoltaic

Gas poWer plants (incl. oil)

source platts, ren21, eWea, GWec, epia, national statistics, iea, breyer. data compilation dr. sven teske/Greenpeace.

references 5

While the official statistic of the Global and chinese Wind industry associations (GWec/creia) adds up to 18,900 mW for 2010, the national enerGy bureau speaks about 13,999 mW. the differences betWeen sources are due to the time of Grid connection, as some turbines Were installed in the last months of 2010 but only connected to the Grid in 2011. these effects also miGht arise in the folloWinG year till 2014.

209

world energy [r]evolution a sustainable world energy outlook

the energy revolution has started on a global level already. this picture becomes even clearer when we look into the global market shares but exclude china, the only country with a massive expansion of coal. about 43% of all new power plants since 2000 have been renewables and 37% have been gas power plants (80% gas + re in total). coal gained a market share of only 12.5% globally, excluding china. the usa and europe installed 44% and 59% of renewables, respectively, and 44% and 36% of gas power plants since 2000. thus new renewables and gas power are the dominating power generation technologies, replacing coal and nuclear and putting both regions on a low-carbon pathway.

8.2 the global market shares in the power plant market: renewables gaining ground

since 2000, the wind power market gained a growing market share within the global power plant market. initially only a handful of countries, namely Germany, denmark and spain, dominated the wind market, but the wind industry now has projects in over 100 countries around the world. the solar photovoltaic industry has experienced similar growth since 2005. between 2000 and 2014, 38% of all new power plants worldwide were renewable-powered â&#x20AC;&#x201C; mainly wind (15.8%) and pv (8.4%), while 22% were gas power plants and 34% coal. thus around 60% of all new power plants installed globally are gas power plants and renewable, with close to one-third as coal. nuclear remains irrelevant on a global scale with just 1% of the global market share for new builds.

figure 8.6 | global and regional power plant market shares 2004 - 2014 6 GLOBAL 1.3%

8.1%

0.2%

GLOBAL, EXCL. CHINA

36.1%

8.1% 12% 14.9%

CHINA

0.4%

15.2%

0.9% 3.1% 63.5%

0.6%

5.8%

12%

USA 9.8%

9.8%

0.5%

EUROPE

0.8%

17.8%

0.4% 5.5%

35.2%

27.3%

16.3%

32.4%

25.6% 3.6% 0.1%

1.4%

44.7%

3.3% 1.9% 0.2%

0.1%

12%

0.7% 8.6%

35.6% 3.1%

3.7%

21.4%

source teske 2015.

references 6

(teske 2015) market analysis based on statistics of platts, ren21, GWec, solarpoWereurope.

210

0.2%

0.1% 1.8%

n n n n n n n n n n

nuclear poWer plants coal poWer plants oil poWer plants Gas poWer plants (incl. oil) biomass Geothermal hydro Wind concentrated solar poWer solar photovoltaic

energy

[r]evolution

8.3 the first decade: the development of the renewable power plant market the renewable energy network for the 21st century (ren21) published its 10th in-depth analysis of the Global renewable energy market analysis – “renewables 2015 – Global status report” in june 2015. With the friendly permission of ren21, this section summarize the main findings of this analysis with regard to renewable power markets and their status in 2014. 8.3.1 the renewable power sector in 2014 ren21’s analysis

in 2014, most renewable energy projects were developed in the power sector. including hydropower, which rose by 3.6 percent to around 1,055 GW, renewable electricity capacity increased worldwide to approximately 1,712 GW by the end of 2014. most of the growth came from non-hydro renewables, which grew by almost 18 percent to an estimated 660 GW. pv and wind posted record capacity additions exceeding new hydropower; taken together, pv and wind made up more than 90 percent of non-hydro added capacity in 2014. including fossil and nuclear additions, renewables still made up around 59 percent of the global market, with several countries posting far higher shares. by the end of 2014, 27.7 percent of global generation capacity was renewable, enough to cover 22.8 percent of global power demand, 16.6 percent of which was hydropower. renewable electricity production is also growing faster than demand. from 2007-2012, electricity consumption grew worldwide by 2.7 percent on average, while renewable power generation increased at an annual rate of 5.9 percent. While electricity consumption in non-oecd countries grew twice as fast as that average, these countries now make up roughly half of investments in renewable energy. variable renewables – pv and wind – have also reached high levels of penetration in numerous countries. in 2014, wind power covered 39 percent of power demand in denmark, 27 percent in portugal, and 21 percent in nicaragua. the highest performers with pv were italy at 7.9 percent of electricity demand, Greece at 7.6 percent, and Germany at seven percent. the leading countries for total installed renewable power generation capacity at the end of 2014 were china, the united states, brazil, Germany, and canada. roughly a quarter of the world’s renewable power capacity was located in china, including some 280 GW of hydropower. excluding hydropower, the leading countries were china, the united states, and Germany, followed by four countries roughly at the same level: italy, spain, japan, and india. the top 20 countries for non-hydro renewable power capacity per capita were all in europe. denmark was far and away the leader, followed by Germany, sweden, spain, and portugal.

outside china – which added the most wind, solar, and hydropower capacity of any country in the world – there was significant market growth elsewhere in asia. for instance, thailand added 0.5 GW of pv – more than many european countries – and significant wind power capacity was built in the philippines and pakistan. renewables made up 78 percent of new generation capacity in the european Union, roughly the level of the past seven years. in Germany, the share of non-hydro renewable electricity grew from 10.5 percent in 2010 to 24 percent in 2014. in scotland, renewables covered nearly half of electricity demand. in north america, pv and wind continued to grow strongly, though the continent has hardly its tremendous resources. more renewable generation capacity was built than gas capacity in the us, and for the first time non-hydro resources produced more electricity than hydropower. brazil continues to be the leader with renewables in latin america and the caribbean. more than 3 GW of hydropower capacity was added in 2014 along with a record 2.5 GW of wind power. but chile and mexico also ramped up wind and pv significantly, while uruguay added the most wind power capacity per capita worldwide. in africa, south africa came in ninth worldwide for solar markets, putting the continent in the top 10 for the first time just ahead of india. south africa also led the continent in wind installations. kenya built more than half of new global geothermal capacity, and rwanda added at least 30 mW of hydropower and an 8.5 mW pv plant. in 2014, large renewable energy projects (more than one megawatt) owned by utilities and key investors continued to dominate global renewable energy production. but australia, europe, japan, and north america have also witnessed significant growth in “prosumers” – power consumers who also produce their own electricity. national dialogues were held in france on how to support and manage this growing group, as did the european union. in both developed and developing countries, industry also got a lot of the energy is needed from biomass waste from agriculture and forestry. development countries with quickly growing energy consumption are developing renewables and fossil fuel capacity simultaneously. in contrast, power consumption is relatively stagnant in numerous oecd countries; they are, renewable energy growth displaces existing generation. some utilities and power providers in europe and north america are therefore shedding fossil fuel investments and taking on renewable energy assets – including acquiring other utilities with such assets. some countries have passed laws requiring utilities to come up with new business models and upgrade grids for the integration of greater shares of renewable electricity. india and africa in particular are building transmission lines to areas with a lot of renewable energy resources. 211

world energy [r]evolution a sustainable world energy outlook

community energy co-ops also grew further in 2014, especially for pv. the first community-owned ocean energy system was built in scotland, and community projects have also gone up from thailand to nova scotia. denmark and Germany have the strongest tradition of local ownership of renewable energy projects. as of 2012, 47 percent of renewable energy investments came from citizens in Germany, though that percentage has fallen since then.

in 2014, corporations and large institutions also increasingly got on board. under the re100 initiative, a group of companies pledged to reach 100 percent renewable energy. the total amount that such firms independently invested in renewables added up to billions of dollars. the mining industry has also discovered renewable energy as a way of reducing energy supply costs at remote locations. mines in brazil, canada, chile, south africa, and tanzania now get some of their heat and/or power from renewables. traditional utilities are voluntarily purchasing renewable energy, especially electricity, even outside of mandates. in 2013, Germany has 5.7 million residential customers subscribing to 100 percent renewable electricity, up from 0.8 million in 2006. by now, nearly a sixth of private households in the country purchase a total of around 20 tWh of renewable electricity. additional commercial customers bring green power purchases up to 30 tWh.

8.4 the global renewable energy market in 2014 the heating and cooling sectors have not grown as quickly as renewable electricity. nonetheless, the market for solar thermal collectors grew by nine percent. in contrast, bio-heat remained nearly unchanged. heat markets often require district heat networks, for instance, so the infrastructure obstacles are greater. uncertain policies further impeded the growth of this market. electric mobility is moving quickly from a low level. in 2013, the number of electric vehicles doubled to 665,000. e- mobility and battery storage, whose cost is also rapidly dropping, are likely to lead to a breakthrough for renewables and transportation. biofuels continued to grow, though at a slower pace; the main obstacle here is sustainability. nonetheless, biofuels remain the primary source of renewable fuel in the transport sector, growing by 8.4 percent to 123.7 billion liters in 2014 (ren21-2015). table 8.1 shows the direct connection between strong renewable energy policies and market growth. up to now, countries with stable, effective policies have had the most success. but as renewable energy becomes cost-competitive and even cheaper than conventional energy, the focus of policymaking will move away from financial incentives towards infrastructure provision, permitting, and levelling the playing field between incumbents and new players.

australia, canada, japan, south africa, and the united states also have green power markets. more than half of americans can subscribe to green power packages from their utility. in the us, 5.4 million customers purchased 62 tWh (roughly 1.7 percent of total us power sales) in 2013.

figure 8.7 | estimated renewable energy share of global electricity production, end-2014

FOSSIL FUELS AND NUCLEAR

77.2%

WIND 3.1% RENEWABLE ELECTRICITY

22.8%

HYDROPOWER

16.6%

BIO-POWER 1.8% SOLAR PV 0.9%

GEOTHERMAL, CSP AND OCEAN

0.4%

source ren21.

212

energy

[r]evolution

table 8.1 | global and regional power plant market shares (teske 2015) start

2004

2013

2014

investment

new investment (annual) in renewable power and fuels

billion usd

232

270

85 800 715 < 36 227 8.9 2.6 0.4 48

560 1,578 1,018 88 396 12.1 138 3.4 319

657 1,712 1,055 93 433 12.8 177 4.4 370

GWth

373

406

billion litres

28.5 2.4

87.8 26.3

94 29.7

48 34 11 n/a n/a 10

144 106 99 55 19 63

164 108 99 60 21 64

power

renewable power capacity (total, not including hydro) renewable power capacity (total, including hydro) hydropower capacity (total) bio-power capacity bio-power generation geothermal power capacity solar pv capacity (total) concentrating solar thermal power (total) wind power capacity (total)

GW GW GW tWh GW GW GW

heat

solar hot water capacity (total) transport

ethanol production (annual) biodiesel production (annual)

billion litres

policies

countries with policy targets states/provinces/countries with feed-in policies states/provinces/countries/ with rps/quota polices countries with tendering/public competive bidding countries with heat obligation/mandate states/provinces/countries with biofuel mandates source ren21-2015.

figure 8.8 | average annual growth rates of renewable energy capacity and biofuels production, end 2009â&#x20AC;&#x201C;2014 50

17 11

10 3.6

5.3

3.5

5.2

3.6

7.1

0 GEOTHERMAL

HYDROPOWER

SOLAR PV

CSP

WIND POWER

SOLAR HEATING

POWER

HEATING

ETHANOL

BIODIESEL

PRODUCTION

TRANSPORT

GROWTH RATE END-2009 THROUGH 2014 GROWTH RATE IN 2014 source ren21 - 2015.

213

e n e r gy r e s o u r c e s a n d s e c u r i t y o f s u p p ly oil

gas

9 the reserves chaos non-conventional oil reserves

nuclear

shale gas

renewable energy

coal

regional renewable energy potential

greenpeace principles and criteria for sustainable bioenergy

“

the only scarcity for solar energy is the lack of political will”

image coastal lagoons with numerous rounded islands are typical of the indian ocean coastline of western australia. these shapes contrast with the angular, white ponds of the salt extraction industry. the area has experienced more direct hits by cyclones than any other place on the western australia’s coastline. the repeated hits almost resulted in a decision to permanently evacuate the small town of onslow (just outside the image). meanwhile, the monte bello islands offshore (just to the north of the image) are guarded as defunct sites of atomic bomb tests.

214

energy

[r]evolution

the issue of supply security is at the top of the energy policy agenda. concern is focused both on price security and the security of physical supply for countries with none if their own resources. in 2013, 78.3% of global final energy demand was met by fossil fuels, while 19.1% came from renewable energy sources and 2.6% from nuclear energy (iea 2014). 1 the unrelenting increase in energy demand conflicts with the finite nature of these resources. at the same time, the global distribution of oil and gas resources does not match the distribution of demand. some countries have to rely almost entirely on fossil fuel imports.

still classified as ‘unconventional’ are included, the resource potentials exceed the current consumption rate by far more than one hundred years. however, serious ecological damage is frequently associated with fossil energy excavation, particularly oil sands and shale oil. over the past few years, new commercial processes have been developed in the natural gas extraction sector, allowing more affordable access to gas deposits previously considered ‘unconventional’, many of which are more frequently found and evenly distributed globally than traditional gas fields. however, tight gas and shale gas extraction can potentially lead to seismic activity and the pollution of groundwater basins and inshore waters. it therefore needs special regulations. a global distribution network for liquid gas already exists, in the form of tankers and loading terminals, so an effective gas market is expected to develop and that oil and gas prices will cease to be linked. having more liquid gas in the energy mix (currently around 10 % of overall gas consumption) significantly increases supply security, such as by reducing the risks of supply interruptions associated with international pipeline networks.

the Global energy assessment (Gea 2012)2 is an integrated assessment of the global energy system to date, involving 300 authors and 200 reviewers worldwide, including scientists, policy experts, and industry leaders. table 1 from that publication shows estimated deposits and the current use of fossil energy resources. there is obviously no shortage of fossil fuels; there might be a shortage of conventional oil and gas, but unconventional resources are still larger than our climate can cope with. reducing global fossil fuel consumption for reasons of resource scarcity alone is not mandatory, even though there may be substantial price fluctuations and regional or structural shortages as we have seen in the past.

Gas hydrates are another type of gas deposit found in the form of methane aggregates both in the deep sea and underground in permafrost. they are solid under high pressure and low temperatures. While there is the possibility of continued greenhouse gas emissions from such deposits as a consequence of arctic permafrost soil thaw or a thawing of the relatively flat siberian continental shelf, there is also potential for extraction of this energy source. many states, including the usa, japan, india, china and south korea have launched relevant research programmes. estimates of global deposits vary greatly; however, all are in the zettajoule range, for example 70,000–700,000 ej (krey et al., 2009).

the presently known coal resources and reserves alone probably amount to around 3,000 times the amount currently mined in a year. thus, in terms of resource potential, currentlevel demand could be met for many hundreds of years to come. coal is also relatively evenly spread across the globe; each continent holds considerable deposits. however, the supply horizon is clearly much lower for conventional oil and gas reserves at 40–50 years. if some resources or deposits currently

table 9.1 | fossil and uranium reserves, resources and occurrences (gea 2012)

historical production through

2015

production

2005

reserves

resources

additional occurrences

conventional oil

6,069

147.9

4,900-7,610

4,170-6,150

unconventional oil

513

20.2

3,750-5,600

11,280-14,800

conventional Gas

3,087

89.8

5,000-7,100

7,200-8,900

unconventional Gas

113

9.6

20,100-67,100

40,200-121,900

6,712

123.8

17,300-21,000

291,000-435,000

conventional uranium

1,218

24.7

2,400

7,400

unconventional uranium

n.a.

coal b

7,100

> 40,000

> 1,000,000

> 2,600,000

a the data reflect the ranges found in the literature; the distinction between reserves and resources is basd on current (exploration and production) technology and market conditions. resource data are not cumulative and do not include reserves. b reserves, resources, and occurrences of uranium are based on once-through fuel cylce operation. closed fuel cycles and breeding technology would increase the uranium resource dimension 50-60 fold. thorium-based fuel cycles would enlarge the fissile-resource base further.

references 1 2

(iea 2014) World enerGy outlook 2014; international enerGy aGency; 9 rue de la fédération; 75739 paris cedex 15, france; WWW.iea.orG; november 2014, isbn: 978 92 64 20804 9 (Gea 2012): Global enerGy assessment - toWard a sustainable future, cambridGe university press, cambridGe, uk and neW york, ny, usa and the international institute for applied systems analysis, laxenburG, austria; WWW.GlobalenerGyassessment.orG

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world energy [r]evolution a sustainable world energy outlook

the Global energy assessment report estimates the theoretical potential to be 2,496 – 2,772,889 ej (Gea, 2012), i.e. possibly more than a thousand times greater than the current annual total energy consumption. the wide range of this estimation shows the high uncertainty how much of the existing reserves can really be exploited. approximately a tenth (1,200–245,600 ej) is rated as potentially extractable. however, the WbGu advised against applied research for methane hydrate extraction, as mining bears considerable risks and methane hydrates do not represent a sustainable energy source (‘the future oceans’, WbGu, 2006). 9.1 the energy [r]evolution fossil fuel pathway

the energy [r]evolution scenario will phase-out fossil fuels not simply as they are depleted, but faster as part of a greenhouse gas reduction pathway required avoiding dangerous climate change. Decisions about opening up new oil, gas and coal mines lead almost certainly to a “lock-in” situation: investments in new oil production will make it more difficult to change to a renewable energy pathway in the future. the energy [r]evolution scenario development aims to organise an energy transition without any new oil exploration and production investments in the arctic or deep sea wells. Unconventional oil such as canada´s tar sands and australia´s shale oil is not needed to guarantee the supply oil until it is phased out under the energy [r]evolution scenario (see chapter 5).

9.1.1 oil

oil is the lifeblood of the modern global economy, as the supply disruptions of the 1970s made clear. oil is the number one source of energy, providing about one third of the world’s needs and the fuel employed almost exclusively for essential uses such as transportation. however, a passionate debate has developed over the ability of supply to meet increasing consumption, a debate obscured by poor information and stirred by recent soaring prices. the reserves chaos

public information about oil and gas reserves is strikingly inconsistent, and potentially unreliable for legal, commercial, historical and sometimes political reasons. the most widely available and quoted figures, those from the industry journals Oil & Gas Journal and World Oil have limited value as they report the reserve figures provided by companies and governments without analysis or verification. moreover, as there is no agreed definition of reserves or standard reporting practice, these figures usually represent different physical and conceptual magnitudes. confusing terminology ‘proved’, ‘probable’, ‘possible’, ‘recoverable’, ‘reasonable certainty’ - only adds to the problem. furthermore estimations oil reserves changes sometimes within only a few years significantly: While the bp statistical review estimated the total global proven oil reserves by the end of 2010 at 1344 thousand million barrel (bp 2011) 3 only 4 years later the same source increased the estimation to 1701 thousand million barrels (bp 2015). 4

table 9.2 | potential emissions as a consequence of the use of fossil reserves and resources (gea 2011)

historical

production

reserves

resources

further

total : reserves ,

factor by which these

production up

2005

G t co 2

occurrences

resources and

emissions alone exceed

2008 Gt

G t co 2

further occurrences

the

co 2

2°c

conventional oil

505

493

386

879

unconventional oil

295

2,640

3,649

6,584

conventional Gas

192

339

455

794

unconventional Gas

2,405

3,197

27,724

33,325

coal

666

1,970

41,277

43,247

total fossil fUels

1,411

5,502

47,954

31,373

84,829

113

emissions budget

potential emissions as a consequence of the use of fossil reserves and resources. also ilustrated is their potential for endangering the 2°c guard rail. this risk is expressed as the factor by which, assuming complete exhaustion of the respective reserves and resources, the resultant co2 emissions would exceed the 750 Gt co2 budget permissible from fossil sources until 2050. the figures refer to co2 alone, other greenhouse gases have not been taken into account. they are based on the values in table 9.2. please note: this table shows corrected values and differs from the printed and ealier pdf versions. source based on table 9.1 and Gea 2011.

references 3 4

(bp 2011) statistical revieW of the World - 2011. (bp 2015 – statistical revieW of the World – 2015; WWW.bp.com.

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energy

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historically, private oil companies have consistently underestimated their reserves to comply with conservative stock exchange rules and for reasons of common business prudence. Whenever a discovery was made, only a portion of the geologist’s estimate of recoverable resources was reported; subsequent revisions would then increase the reserves from that same oil field over time. national oil companies, mostly represented by opec (organisation of petroleum exporting countries), have taken a very different approach. they are not subject to any sort of accountability, and their reporting practices are even less clear. in the late 1980s, the opec countries blatantly overstated their reserves while competing for production quotas, which were allocated as a proportion of the reserves. although some revision was needed after the companies were nationalised, between 1985 and 1990, opec countries increased their apparent joint reserves by 82%. not only were these dubious revisions never corrected, but many of these countries have reported untouched reserves for years, even if no sizeable discoveries were made and production continued at the same pace. additionally, the former soviet union’s oil and gas reserves have been overestimated by about 30% because the original assessments were later misinterpreted. Whilst private companies are now becoming more realistic about the extent of their resources, the opec countries hold by far the majority of the reported reserves, and their information is as unsatisfactory as ever. their conclusions should therefore be treated with considerable caution. fairly estimating the world’s oil resources would require a regional assessment of the mean backdated (i.e. ‘technical’) discoveries. non-conventional oil reserves

a large share of the world’s remaining oil resources is classified as ‘non-conventional’. potential fuel sources such as oil sands, extra heavy oil and oil shale are generally more costly to exploit, and their recovery causes enormous environmental damage. the reserves of oil sands and extra heavy oil worldwide amount to an estimated 6 trillion barrels, 1 to 2 trillion of which are believed to be recoverable if the oil price is high enough and the environmental standards low enough. one of the worst examples of environmental degradation resulting from the exploitation of unconventional oil reserves is the oil sands beneath the canadian province of alberta. they constitute the world’s second-largest proven oil reserves after saudi arabia. producing crude oil from these ‘tar sands’ - a heavy mixture of bitumen, water, sand and clay found beneath more than 54,000 square miles 5 of old-growth forest in northern alberta, an area the size of england and

Wales – releases up to four times more carbon dioxide, the principal global warming gas, than conventional drilling does. the booming oil sands industry will produce 100 million tonnes of co 2 a year (equivalent to a fifth of the uk’s entire annual emissions) by 2012, ensuring that canada would have missed its emission targets under the kyoto protocol. the oil rush is also scarring a wilderness landscape: millions of tonnes of plant life and top soil are scooped away in vast opencast mines, with millions of litres of water diverted from rivers. up to five barrels of water are needed to produce a single barrel of crude, and the process requires huge amounts of natural gas. it takes two tonnes of the raw sands to produce a single barrel of oil. furthermore the exploitation of tar sands is significantly more expensive than conventional oil production. according to university of michigan – center for sustainable systems (css – 2014) 6 the production cost of oil sands range between 6.6 and 13.1 $/Gj while conventional oil production costs are estimated between 1.6 to 6.6 §/Gj. thus, tar sands ar only economical when the price of conventional oil is high. these production costs do not include the enormous environmental and climate damages. 9.1.2 gas

natural gas has been the fastest growing fossil energy source over the last two decades, boosted by its increasing share in the electricity generation mix. Gas is generally regarded as an abundant resource; public concerns about depletion are limited to oil, even though few in-depth studies address the subject. Gas resources are more concentrated, and a few massive fields make up most of the reserves. the largest gas field in the world holds 15% of the ultimate recoverable resources (urr), compared to 6% for oil. unfortunately, information about gas resources suffers from the same bad practices as oil data because gas mostly comes from the same geological formations, and the same stakeholders are involved. most reserves are initially understated and then gradually revised upwards, giving an optimistic impression of growth. by contrast, russia’s reserves, the largest in the world, are considered to have been overestimated by about 30%. owing to geological similarities, gas follows the same depletion dynamic as oil, and thus the same discovery and production cycles. in fact, existing data for gas is of worse quality than for oil, with ambiguities arising over the amount produced, partly because flared and vented gas is not always accounted for. as opposed to published reserves, the technical ones have been almost constant since 1980 because discoveries have roughly matched production.

references 5 6

The IndePendenT, 10 december 2007. (css 2014) center for sustainable systems; university of michiGan. 2014. “unconventional fossil fuels factsheet.” pub. no. css13-19. october 2014.

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world energy [r]evolution a sustainable world energy outlook

9.1.3 shale gas

natural gas production, especially in the united states, has recently involved a growing contribution from nonconventional gas supplies such as shale gas. conventional natural gas deposits have a well-defined geographical area. the reservoirs are porous and permeable, and the gas is produced easily through a wellbore. it does not generally require artificial stimulation (inGaa 2008). 7

natural gas obtained from unconventional reserves (known as “shale gas” and “tight gas”) requires the reservoir rock to be fractured using a process known as hydraulic fracturing or “fracking”. fracking is associated with a range of environmental impacts, some of which are not fully characterized or understood. in addition, it appears that the greenhouse gas “footprint” of shale gas production may be significantly greater than of conventional gas, possibly even worse than of coal. in the us, the country with the highest production of shale gas globally, experience shows a huge negative environmental impact (css 2014). a single gas well requires one to two hectares of land, in addition to road

networks. the drilling fluid, or “mud,” is used to cool the drill bit, regulate pressure, and remove rock fragments. one well may require hundreds of tonnes of mud and produce 100 to 550 tonnes of rock cuttings. furthermore, small to moderate magnitude (<6) seismic activity has been linked to underground injection of wastewater produced in oil and gas operations, including a 5.3 and a 5.6 magnitude earthquake in 2011 (css 2014). research and investment in non-conventional gas resources has increased significantly in recent years due to the rising price of conventional natural gas. in some areas, the technologies for economic production have already been developed, in others it is still at the research stage. extracting shale gas, however, usually goes hand in hand with environmentally hazardous processes. even so, it is expected to increase. greenpeace opposes the exploitation of unconventional gas reserves. these resources are not needed to guarantee the needed gas supply under the energy [r]evolution scenario.

table 9.3 | assumptions on fossil fuel use in the energy [r]evolution scenario

2012

2015

2020

2025

2030

2035

2040

2045

2050

conventional oil

161,342 167,429 176,000 183,891 191,839 196,748 201,700 205,204 208,159 26,363 27,358 28,758 30,048 31,346 32,148 32,958 33,530 34,013

reference [pj/a] reference [million barrels] enerGy [r]evolution [pj/a] enerGy [r]evolution [million barrels] advanced enerGy [r]evolution [pj/a] advanced enerGy [r]evolution [million barrels]

161,342 166,364 158,258 138,610 115,473 90,018 26,363 27,184 25,859 22,649 18,868 14,709

66,523 10,870

48,024 7,847

33,791 5,521

161,342 166,364 156,426 132,421 103,516 71,952 26,363 27,184 25,560 21,637 16,914 11,757

45,901 7,500

27,375 4,473

14,744 2,409

gas

118,747 121,555 131,936 145,473 159,631 176,219 193,201 208,781 217,258 3,199 3,472 3,828 4,201 4,637 5,084 5,494 5,717 3,125

reference [pj/a] reference [billion cubic metres

= 10e9m]

enerGy [r]evolution [pj/a] enerGy [r]evolution [billion cubic metres advanced enerGy [r]evolution [pj/a] advanced enerGy [r]evolution [billion cubic metres coal (harD coal

118,747 122,091 129,644 128,942 125,232 113,681 97,858 3,125 3,213 3,412 3,393 3,296 2,992 2,575

74,180 1,952

50,419 1,327

118,747 122,059 130,861 129,841 124,606 107,041 82,188 = 10e9m] 3,125 3,212 3,444 3,417 3,279 2,817 2,163

45,360 1,194

8,715 229

= 10e9m]

lignite)

reference [pj/a] reference [million tonnes] enerGy [r]evolution [pj/a] enerGy [r]evolution [million tonnes] advanced enerGy [r]evolution [pj/a] advanced enerGy [r]evolution [million tonnes]

154,241 169,064 183,737 198,385 213,587 226,741 240,051 247,154 250,765 8,317 8,967 9,641 10,344 11,038 11,656 12,291 12,666 12,853 154,241 165,787 161,569 140,973 109,218 75,832 8,317 8,773 8,282 6,859 5,040 3,443

50,437 2,264

30,367 1,342

17,680 768

154,241 165,997 156,883 131,157 94,693 8,317 8,782 8,078 6,432 4,409

33,487 1,528

16,826 753

11,647 506

source ?

references 7

(inGaa 2008)interstate natural Gas association of america (inGaa), “availability, economics and production potential of north american unconventional natural Gas supplies”, november 2008.

218

58,495 2,690

energy

[r]evolution

9.1.4 coal

coal was the world’s largest source of primary energy until it was overtaken by oil in the 1960s. today, coal supplies almost one quarter of the world’s energy. however, it is the biggest contributor of carbon emissions among all energy sources, even ahead of oil. despite being the most abundant of fossil fuels, coal’s development is currently threatened by environmental concerns; hence, its future will unfold in the context of both energy security and global warming. coal is abundant and more equally distributed throughout the world than oil and gas. Global recoverable reserves are the largest of all fossil fuels, and most countries have at least some. moreover, existing and prospective big energy consumers like the us, china and india have been selfsufficient in coal, but the situation has changed over the past years. the usa is now a net exporter, while china is a net importer of coal. While hard coal is a widely used fuel, lignite or brown coal is used only in 18 countries for power generation. this mirrors the available resources. the total reserves for hard coal are estimated with 18,246 ej (consumption 2013 132.6 ej/a), while lignite reserves are estimated at 2,775 ej (consumption 2013 21.6 ej/a) (Gea 2012). coal has been exploited on a large scale for two centuries, so both the product and the available resources are well known; no substantial new deposits are expected to be discovered. extrapolating the demand forecast forward, the world will consume 20% of its current reserves by 2030 and 40% by 2050. hence, if current trends are maintained, coal would still last several hundred years.

conventional uranium resources are defined as those occurrences from which uranium is recoverable as a primary product, a co-product, or an important by-product. uranium reserves are periodically estimated by the oecd’s nuclear energy agency (nea) and the international atomic energy agency (iaea) with input from the World nuclear association (Wna), the World energy council (Wec), and numerous national geological institutions. nea-iaea estimates have the widest coverage, so the reserves reported in their latest survey (the so-called red book) are given here (nea/iaea, 2014). the two organizations define ‘identified reserves’ as deposits that could be produced competitively in an expanding market. until 2008, it included uranium recoverable at less than 130 $/kgu. stimulated by high spot prices of up to 350 $/kg in 2007 (Gea 2012), the 2010 edition of the red book extended the cost ranges to 260 $/kgu, which had not yet further been increased as of 2014 (oecdnea 2014). 8 secondary sources, such as old deposits, currently make up nearly half of worldwide uranium reserves. however, these will soon be used up. mining capacities will have to be nearly doubled in the next few years to meet current needs. a joint report by the oecd nuclear energy agency and the international atomic energy agency 9 estimates that all existing nuclear power plants will have used up their nuclear fuel, employing current technology, within less than 70 years. Given the range of scenarios for the worldwide development of nuclear power, it is likely that uranium supplies will be exhausted sometime between 2026 and 2070. this forecast includes the use of mixed oxide fuel (mox), a mixture of uranium and plutonium.

9.1.5 nuclear

uranium, the fuel used in nuclear power plants, is a finite resource whose economically available reserves are limited. its distribution is almost as concentrated as oil and does not match global consumption. five countries - canada, australia, kazakhstan, russia and niger - control three quarters of the world’s supply, while on canada and russia operate their own nuclear power plants. as a significant user of uranium, however, russia’s reserves will be exhausted within ten years.

the maps on the following pages provide an overview of the availability of different fuels and their regional distribution. information in this chapter is based partly on the report ‘plugging the gap’, 10 as well as information from the international energy agency´s world energy outlook 2014 and bp statistical review 2015. map 1 oil / map 2: gas / map 3: coal / map 4: nuclear / map 5: solar / map 6: wind

references 8 9 10

(oecd nea-2014) uranium 2014:resources, production and demand; oecd nuclear enerGy aGency; 12, boulevard des Îles; 92130 issy-les-moulineaux, france; WWW.oecd-nea.orG. (oecd nea 2003) ‘uranium 2003: resources, production and demand’. (res 2007) ‘pluGGinG the Gap - a survey of World fuel resources and their impact on the development of Wind enerGy’, reneWable enerGy systems ltd (res); beaufort court eGG farm lane; kinGs lanGley herts Wd4 8lr; united kinGdom; Web: WWW.res-Group.com.

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9.2 renewable energy nature offers a variety of freely available options for producing energy. their exploitation is mainly a question of how to convert sunlight, wind, biomass or water into electricity, heat or power as efficiently, sustainably and costeffectively as possible.

on average, the energy in the sunshine that reaches the earth is about one kilowatt per square metre worldwide. according to the ipcc special report renewables (srren), 12 solar energy reaches the earth at a rate 7,900 times greater than current energy consumption. in one day, the earth gets enough energy from the sun to satisfy the worldâ&#x20AC;&#x2122;s current energy requirements for twenty years, even before other renewable energy sources such as wind and ocean energy are taken into account. even though only a percentage of that potential is technically accessible, there is still enough to provide up to ten times more energy than the world currently requires. the Global energy assessment (Gea 2012) report provides a slightly higher estimation of renewable energy resources shown in table 9.5; however, both sources prove that the availability of the resource on a global scale is not a constraint.

table 9.4 | renewable energy potential (ipcc â&#x20AC;&#x201C; special report renewable energy) renewable source

annual flux

ratio ( annual energy

ej / yr

flux

/ 2008

box 9.2 | definition of types of energy resource potential 11

theoretical potential: the physical upper limit of the energy available from a certain source. for solar energy, for example, this would be the total solar radiation falling on a particular surface. conversion potential: derived from the annual efficiency of the respective conversion technology, it is therefore not a strictly defined value, since the efficiency of a particular technology depends on technological progress. technical potential: this takes into account additional restrictions regarding the area realistically available for energy generation. technological, structural and ecological restrictions and legislative requirements are accounted for. economic potential: the proportion of the technical potential that can be utilised economically. biomass, for example, is included if it can be exploited economically in competition with other products and land uses. sustainable potential: the potential of an energy source is limited based on an evaluation of ecological and socioeconomic factors.

table 9.5 | renewable energy flows, potential, and utilization in ej of energy inputs provided by nature total reserve

renewable source

primary

utilization

technical potential

annual flows

ej /a

energy supply

bioenerGy

1,548

3.1

biomass, msW, etc.

46.3

160-270

2,200

solar enerGy

3,900,000

7,900

Geothermal

2.3

810-1,545

1,500

Geothermal enerGy

1,400

2.8

hydropoWer

11.7

50-60

200

hydropoWer

147

0.30

solar enerGy

0.5

62,000-280,000

3,900,000

ocean enerGy

7,400

Wind enerGy

1.3

1,250-2,250

110,000

Wind enerGy

6,000

ocean enerGy

3,240-10,500

1,000,000

source srren 2011

references 11 12

WbGu (German advisory council on Global chanGe). (srren 2011) ipcc, 2011: ipcc special report on reneWable enerGy sources and climate chanGe mitiGation. prepared by WorkinG Group iii of the interGovernmental panel on climate chanGe [o. edenhofer, r. pichsmadruGa, y. sokona, k. seyboth, p. matschoss, s. kadner, t. ZWickel, p. eickemeier, G. hansen, s. schlĂśmer, c. von stechoW (eds)]. cambridGe university press, cambridGe, united kinGdom and neW york, ny, usa, 1075 pp.

220

source Gea 2012

energy

[r]evolution

the overall technical potential of renewable energy is several times greater than current total energy demand. technical potential is defined as the amount of renewable energy output obtainable by full implementation of demonstrated technologies or practices likely to develop. it takes into account the primary resources, the socio-geographical constraints and the technical losses in the conversion process. the complexity of calculating renewable energy potentials is particularly great because these technologies are comparatively young and their exploitation involves changes to the way in which energy is both generated and distributed. the technical potential depends on a number of uncertainties; for instance, a technology breakthrough could have a dramatic impact, changing the technical potential assessment within a very short time frame. further, because of the speed of technology change, many existing studies are based on out-of-date information. more recent data, such as significantly increased average wind turbine capacity factors and output, would increase the technical potentials still further (sreen, may 2011). a wide range of estimates is provided in the literature but studies have consistently found that the total global technical potential for renewable energy is substantially higher than both current and projected future global energy demand. solar has the highest technical potential amongst the renewable sources, but substantial technical potential exists for all forms (srren, may 2011).

taking into account the uncertainty of technical potential estimates, figure 1 provides an overview of the technical potential of various re resources in the context of current global electricity and heat demand as well as global primary energy supply. issues related to technology evolution, sustainability, resource availability, land use and other factors that relate to this technical potential are explored in the relevant chapters. the regional distribution of technical potential is addressed in chapter 10. the various types of energy cannot necessarily be added together to estimate a total, because each type was estimated independently of the others (for example, the assessment did not take into account land use allocation; for instance, pv and concentrating solar power cannot occupy the same space when a particular site is suitable for either). Given the large unexploited resources, even without having reached the full development limits of the various technologies, it can be concluded that the technical potential is not a limiting factor in the expansion of renewable energy generation. it will not be necessary or desirable to exploit the entire technical potential. implementation of renewable energy has to respect sustainability criteria in order to achieve a sound future energy supply. public acceptance is crucial, especially bearing in mind that the decentralised character of many renewable energy technologies will move systems closer to consumers. Without public acceptance, market expansion will be difficult or even impossible.

figure 9.1 | globaly averaged combined land and ocean surface temperature anomaly

ELECTRICITY

HEAT

PRIMARY ENERGY

Global technical potential, log scale

100,000

10,000

1,000

GLOBAL HEAT DEMAND

2008: 164 EJ

GLOBAL PRIMARY ENERGY SUPPLY

2008: 492 EJ

100

MAX

GLOBAL ELECTRICITY DEMAND

2008: 61 EJ

RANGE OF ESTIMATES

EJ/yr 0

MIN GEOTHERMAL

HYDROPOWER

ENERGY

OCEAN

WIND

GEOTHERMAL

ENERGY

580 85

312 10

BIOMASS

DIRECT SOLAR ENERGY

RANGE OF ESTIMATES OF GLOBAL TECHNICAL POTENTIALS Max EJ/yr Min EJ/yr

1,109 118

52 50

331 7

500 50

49,837 1,575

source srren 2011 note biomass and solar are shown as primary energy due to their multiple uses. note that the figure is presented in logarithmic scale due to the wide range of assessed data.

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world energy [r]evolution a sustainable world energy outlook

in addition to the theoretical and technical potential discussions, this report also considers the economic potential of renewable energy sources, taking into account all social costs and assuming perfect information (covered in section 10.6) and the market potential of re sources. market potential is defined in box 9.2, but the term often used in different ways. the general understanding is that market potential means the total amount of renewable energy that can be implemented in the market, taking into account existing and expected real-world market conditions (covered in section 10.3) shaped by policies, availability of capital and other factors, each of which is discussed in ar4 and defined in annex i. the market potential may therefore in theory be larger than the economic potential. to be realistic, however,

market potential analyses have to take into account the behaviour of private economic agents under specific prevailing conditions, which are of course partly shaped by public authorities. the energy policy framework in a particular country or region will have a profound impact on the expansion of renewables. before looking at the possible regional contribution renewable energy can make, it is worth understanding the upper limits of the regional potential of each source to develop an optimal mix in terms of technical and economic circumstances.

9 figure 9.2 | renewable energy potential analysis

571 EJ/y

193 EJ/y 864 EJ/y

306 EJ/y

IN EJ/Y FOR

193 EJ/y

1,335 EJ/y

TOTAL TECHNICAL RE POTENTIAL

464 EJ/y

2050 BY

RENEWABLE ENERGY SOURCE: SOLAR

761 EJ/y

WIND

X EJ/y

5,360 EJ/y

GEOTHERMAL

1,911 EJ/y

HYDRO OCEAN BIO ENERGY

MAP: TECHNICAL RE POTENTIAL CAN SUPPLY THE

2007 PRIMARY ENERGY

DEMAND BY A FACTOR OF:

0-2.5

2.6-5.0

5.1-7.5

7.6-10

10-12.5

12.6-15

15.1-17.5

17.6-20 20.1-22.5 22.6-25

25-50

over 50

WORLD

11,941 EJ/Y

source ippc/srren. note the technical re potentials reported here represent total worldwide and regional potentials based on a review of studies published before 2009 by krewitt et al. (2009). they do not deduct any potential already utilized for energy production. due to methodological differences and accounting methods among studies, these estimates cannot be strictly compared across technologies and regions, nor in terms of primary energy demand. technical re potential analyses published after 2009 show higher results in some cases but are not included in this figure. some re technologies may compete for land, possibly lowering the overall re potential. scenario data: iea Weo 2009 reference scenario (international energy agency (iea), 2009; teske et al., 2010), remind-recipe 450ppm stabilization scenario (luderer et al., 2009), minicam emf22 1st-best 2.6 W/2 overshoot scenario (calvin et al., 2009), advanced energy [r]evolution 2010 (teske et al., 2010).

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9.3 greenpeace principles and criteria for sustainable bioenergy clearly, the biggest potential that the terrestrial environment offers for climate change mitigation lie in a radical change in the way we use land resources and not in just maximizing the amount of biomass available to burn. strict criteria for bioenergy, adequate policies, institutional frameworks and enforcement capacities are needed to safeguard environmental, climate and social benefits and ensure that this scarce resource is used in the most effective manner. this must include the following principles and criteria (in random order): principles

• bioenergy production must not cause negative impacts on the world’s natural capital, such as forests and other natural ecosystems, biodiversity, soil fertility and water resources. • bioenergy production must not cause negative impacts on livelihoods, nor on people’s access to nutritious and healthy food. land and water grabbing, land use conflicts and other social conflicts must be prevented. • bioenergy must not widen social inequalities between developing and developed countries. international trade in biomass or biofuels must not undermine food security. production for local needs should take priority over production for the global market. • bioenergy production must be as resource efficient as possible, and deliver significant reductions in greenhouse gas emissions compared to fossil fuel-based energy systems. • biomass must be utilized for energy following the cascading use principle. under this principle biomass is preferably used for maintaining soil fertility, food, feed and materials that store carbon. 13 bioenergy should not compete with these sectors for biomass feedstock. policies that incentivize the production of bioenergy (and thereby create a market) must enhance instead of distort the cascading use of biomass. • in order to close nutrient cycles and reduce co 2 emissions, bioenergy should preferably be produced from regionally available biomass and satisfy regional energy need. • energy demand reductions must be prioritised so as to reduce the volume of bioenergy required to secure a supply of 100% renewable energy. • biomass for bioenergy should preferably be utilized in applications where it delivers the highest co 2 savings. • bioenergy for electricity should be used for dispatching and not for large base load capacity.

criteria greenhouse gas emissions

• any bioenergy project should replace energy produced from fossil fuels. considering the entire production chain, aboveground and below-ground carbon stock changes and any indirect land use changes (iluc), the net greenhouse gas emission reduction of such a project must be at least 50% compared to a natural gas reference, 60% compared to an oil reference and 70% compared to a coal reference. this net emission reduction must be realized within 20 years. 14 • Greenhouse gas emissions as a result of indirect land use change (iluc) must be integrated in the greenhouse gas calculation methodology of crops (including trees) for bioenergy, grown on agricultural land, by determining cropspecific iluc-factors. • Whether commercial, non-commercial, diseased or firedamaged, standing trees from (semi)natural forests must not be cut specifically for bioenergy because of the large upfront carbon debt that is created. • tree harvest levels in forests must not be increased as a result of bioenergy production. • land with a high carbon stock (forests, woodlands, peatlands, grasslands) must not be converted. 15, 16 biodiversity

• bioenergy production must not be extracted from high conservation value areas (hcvas) and must not cause direct or indirect destruction, conversion or degradation of valuable ecosystems, such as forests, woodlands, peatlands and grasslands. • bioenergy production must not cause a loss of biodiversity in agro-ecosystems. • in forests that are managed for wood production, woody biomass should only be used for bioenergy production if it is proven to be sourced from responsibly managed forests and plantations, equivalent to or exceeding the standard of the forest stewardship council (fsc). 17 • no deliberate release of genetically engineered (Ge) organisms to the environment must be permitted. any bioenergy crops, including trees, must not be Ge. Ge microbes (including those developed by synthetic biology) must only be used in securely-contained facilities. references 13

15 16 17

Greenpeace does not necessarily value feed above enerGy. the livestock sector is larGely unsustainable and should be stronGly decreased in most parts of the World. hoWever, the competition effect of a policy driven bioenerGy market With the food and feed market lead to uncontrollable neGative effects, mainly indirect land use chanGe (iluc), Which can undermine the environmental benefits of bioenerGy. the calculation must include emissions from cultivation, extraction, processinG, storaGe, transport, and smokestack emissions (burninG biomass is not carbon neutral). When burninG biomass, the net Greenhouse Gas emissions over a period of 20 years must be accounted for, aGainst the reference scenario of not usinG the biomass for bioenerGy. Grasslands store approximately 34% of the Global stock of carbon in terrestrial ecosystems While forests store approximately 39%. Greenpeace (2013), identifyinG hiGh carbon stock (hcs) forest for protection, http://m.Greenpeace.orG/international/Global/international/briefinGs/forests/2013/hcs-briefinG-2013.pdf at this moment, only the fsc principles and criteria are sufficient to Guarantee responsible manaGement of forests. see WWW.fsc.orG. this applies to all Wood products, Whether bioenerGy is involved or not.

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world energy [r]evolution a sustainable world energy outlook

• crops and plantations must protect, conserve and restore native biodiversity on farm level, which means that they must not concentrate on monocultures. • the expansion and development of new bioenergy crops, plantations and/or tree plantings, must not introduce any invasive species. Where there is doubt, the precautionary principle must be applied. environment

• the production of bioenergy from crops or residues must maintain ecosystem services: water filtration, water quality and quantity, nutrient recycling, soil organic carbon, overall soil fertility and pollination.

• ecological farming practices must be applied that do not pollute the biosphere through the accumulation of agrochemicals, such as synthetic fertilizers, pesticides and herbicides, in the soil, water or air. the use of agrochemicals must be minimised and ultimately phased out, which means that their use must be limited to when there is no biological or organic alternative and to only the most-efficient and non-polluting methods. 18 social justice

• bioenergy production must not cause direct or indirect destruction of, or transfer of land away from existing peasant, indigenous, and/or nomadic agricultural/agropastoral/pastoral systems. • local food security, livelihoods, stakeholder rights and land rights by local communities who live off the land must be respected and strengthened, in line with the tenure guidelines of the un committee on World food security (cfs).19 • indigenous peoples and local communities must have the right to free and prior informed consent for the use of their land. • labour rights must be respected according to the international labour organization (ilo) standards. 20 verification and transparency

• above criteria must be verified by an accredited and transparent third party to prove that these criteria are met. • information about the volume, specific feedstock and feedstock origin of the bioenergy that each individual energy company brings to the market must be publicly available.

references 18 19

obviously this applies to all aGriculture, Whether bioenerGy production is involved or not. united nations (un) committee on World food security (cfs) (2012), voluntary Guidelines on the responsible Governance of tenure of land , fisheries and forests in the context of national food security, http://WWW.fao.orG/cfs/cfs-home/cfs-land-tenure/en/ . international labour orGaniZation (ilo), international labour standards, http://WWW.ilo.orG/Global/standards/lanG--en/index.htm.

224

9.3.1 policy recommendations

bioenergy can only be ecologically sound if coming from sustainable and responsible sources and land uses. large scale bioenergy production currently leads to uncontrollable negative impacts because most land is not managed in a sustainable way. this is why Greenpeace foresees a relatively small role for bioenergy in the transition towards 100% renewable energy. the constraints in the sphere of governance are too complex to realistically adopt and promote a large role for bioenergy in a socially and ecological sustainable way. Greenpeace advises governments and companies to be very cautious with policies related to bioenergy, to apply all the principles and criteria listed in this document and to make sure that acquisition of bioenergy feedstock does not lead to damage to ecosystems, avoids competition with soil fertility maintenance, food production and the production of materials that store carbon. the precautionary principle should guide the development and implementation of bioenergy policies. the enforcement of a robust institutional framework must prevent negative social and environmental impacts. Governments must prioritize sustainable land use policies, from ecological farming to effective forest protection. 9.3.2 bioenergy and climate

the international accounting rules for greenhouse gas emissions, as agreed upon within the united nations framework convention on climate change (unfccc) contain a major flaw regarding accounting for the greenhouse gas emissions of bioenergy. Greenhouse gas emissions due to land use, land use change and forestry (lulucf) should be reported in the national greenhouse gas inventories of annex 1 parties under the kyoto protocol. subsequently, smokestack greenhouse gas emissions from biomass combustion are set to zero, to avoid double counting. however, in practise a lot of biomass that is burned in annex 1 countries comes from non-annex 1 countries and not all annex 1 countries report lulucf emissions. furthermore, while reporting land use and land use changes emissions is mandatory for annex 1 countries, reporting forestry emissions is only optional. on top of that, due to indirect land use change (iluc), land use change is taking place in non-annex 1 countries, as a result of bioenergy policies in annex 1 countries. despite this, all bioenergy is accounted for as climate neutral leading to an enormous carbon accounting error. therefore, carbon accounting schemes should stop assuming ‘carbon neutrality’ of bioenergy and account for the net direct and indirect greenhouse gas performance of bioenergy as outlined in the sustainability criteria for bioenergy presented in this document.

energy

[r]evolution

bioenergy and sustainable land use

• agriculture has to be based on sustainable land use management practices. a shift is needed from industrial agriculture towards ecological farming based on closed nutrient and water cycles. agricultural residues can only be used for bioenergy in limited amounts. policies that promote bioenergy made from agricultural residues should not enhance unsustainable industrial agriculture. • in countries that produce forest biomass, governments should impose strict biomass sourcing policies that would stop companies from cutting down standing trees for energy production. • livestock production uses 75% of agricultural land, including both the land used to grow crops for animal feed and pasture and grazing lands. Whether there will be space for growing dedicated energy crops on agricultural land in a responsible way in the future depends, amongst many other factors, on the development of the diet of populations around the world. consuming less animal protein reduces significantly the surface of agricultural land needed for food production. policies are therefore needed that disincentivise animal protein consumption. bioenergy and the energy transition

• access to clean renewable energy must be delivered for all. apart from being inefficient and time consuming, most traditional use of biomass in developing countries leads to respiratory problems for its users and degradation of forests and woodland resources, as well as soil erosion and degradation. clean energy access must therefore be prioritized for communities that still depend on traditional biomass for cooking and heating. this is a ‘low-hanging fruit’ that could combine a strong increase in welfare with environmental protection and nature conservation.

• according to the polluter-pays-principle, subsidies for bioenergy production must not make fundamentally unsustainable industries more competitive. examples are co-firing of biomass with coal in coal-fired power plants or digestion of animal manure produced by intensive livestock operations for meat and dairy production. the latter must be required to mitigate methane emissions, but this should not be subsidized. • in biomass importing countries, governments should not rely on bioenergy for meeting renewable energy targets. the share of bioenergy must be capped. • in biomass-importing countries, governments should not rely on bioenergy for meeting renewable energy targets. the share of bioenergy must be capped. • the transition to 100% renewable energy entails a radical system change, and bioenergy policies should not block nor delay this change. replacing gasoline and diesel with biofuels within the infrastructure of the oil industry and within inefficient internal combustion engines does not trigger a system change, nor does replacing coal with wood in coal power plants. • sustainable bioenergy, which is an inherently a limited available energy source, should be part of a long term strategy that leads to 100% renewable energy. sustainable bioenergy should not be utilized for large-scale base load electricity production, but for dispatching in the electricity sector, heat production and as biofuel in aviation, shipping and heavy road transport. maximising energy savings is fundamental. Greenpeace’s energy [r]evolution provides a pathway towards reaching these objectives. • biofuel blending targets in the transport sector should be replaced by energy savings and renewable energy targets, with a focus on a shift to electric transport and truly sustainable biofuels produced according to the principles and criteria presented in this paper.

225

e n e r gy t e c h n o lo g i e s fossil fuel technologies

nuclear technologies

renewable energy technologies

renewable heating and cooling technologies

“

technologies which convert solar and wind into energy are likely to gain the largest market shares”

image located well north of the arctic circle, uummannaq island is home to one of the most northerly towns in greenland. the sun never drops below the horizon for nearly three months in summer, and winter brings months of darkness. sea ice still surrounded the island, but breaks in the ice—called leads—expose seawater beneath it. usually, sea ice around uummannaq breaks up and drifts away by the end of may. home to about 1,200 people, the town of uummannaq lies on the southern tip of the island.

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[r]evolution

this chapter describes the range of technologies available now and in the future to satisfy the world’s energy demand. the energy revolution scenario is focused on the potential for energy savings and renewable sources, primarily in the electricity and heat generating sectors. 10.1 fossil fuel technologies the most commonly used fossil fuels for power generation around the world are coal and gas. oil is still used where other fuels are not readily available, for example islands or remote sites, or where there is an indigenous resource. together, coal and gas currently account for 63% of global electricity supply (iea 2015). 1 10.1.1 coal combustion technologies

in a conventional coal-fired power station, pulverised or powdered coal is blown into a combustion chamber where it is burned at high temperature. the resulting heat is used to convert water flowing through pipes lining the boiler into steam. this drives a steam turbine and generates electricity. over 90% of global coal-fired capacity uses this system. pulverized coal is still the most widely used fuel source and coal power plants, but supercritical conditions have become more common in modern coal plants in order to increase efficiency. steam-drum boilers are still the norm, however, and they limit total efficiency to roughly 40 percent of the fuel’s lower heating value (lhv). at the beginning of the century, state-of-the-art supercritical coal plants, in contrast, reached thermal efficiencies up to 47 percent of lhv (ieacoal online). 2 coal power stations can vary in capacity from one block of few hundred megawatts up to ten or more blocks with a total capacity of several thousand megawatts.a number of technologies have been introduced to improve the environmental performance of conventional coal combustion. these include coal cleaning (to reduce the ash content) and various ‘bolt-on’ or ‘end-of-pipe’ technologies to reduce emissions of particulates, sulphur dioxide and nitrogen oxide, the main pollutants resulting from coal firing apart from carbon dioxide. flue gas desulphurisation (fGd), for example, most commonly involves ‘scrubbing’ the flue gases using alkaline sorbent slurry, which is predominantly lime or limestone based. more fundamental changes have been made to the way coal is burned both to improve its efficiency and further reduce emissions of pollutants (Wca 2015). 3 these include:

• integrated Gasification combined cycle: coal is not burned directly but reacted with oxygen and steam to form a synthetic gas composed mainly of hydrogen and carbon monoxide. this is cleaned and then burned in a gas turbine to generate electricity and produce steam to drive a steam turbine. iGcc improves the efficiency of coal combustion from 38-40% up to 50%. • supercritical and ultra supercritical: these power plants operate at higher temperatures than conventional combustion, again increasing efficiency towards 50%. • fluidised bed combustion (fbc): coal is burned in a reactor comprised of a bed through which gas is fed to keep the fuel in a turbulent state. this improves combustion, heat transfer and the recovery of waste products. by elevating pressures within a bed, a high-pressure gas stream can be used to drive a gas turbine, generating electricity. emissions of both sulphur dioxide and nitrogen oxide can be reduced substantially (Wca 2015). • pressurised pulverised coal combustion: mainly being developed in Germany, this is based on the combustion of a finely ground cloud of coal particles creating highpressure, high-temperature steam for power generation. the hot flue gases are used to generate electricity in a similar way to the combined cycle system. other potential future technologies involve the increased use of coal gasification. underground coal Gasification, for example, involves converting deep underground unworked coal into a combustible gas which can be used for industrial heating, power generation or the manufacture of hydrogen, synthetic natural gas or other chemicals. the gas can be processed to remove co 2 before it is passed on to end users. demonstration projects are underway in australia, europe, china and japan. 10.1.2 gas combustion technologies

natural gas can be used for electricity generation through the use of either gas or steam turbines. for the equivalent amount of heat, gas produces about 45% (iea etp 2014) 4 less carbon dioxide during its combustion than coal. Gas turbine plants use the heat from gases to directly operate the turbine. natural gas fuelled turbines can start rapidly and are therefore often used to supply energy during periods of peak demand, although at higher cost than base load generation power plants.

references 1 2

3 4

(iea 2015) enerGy climate andchanGe; World enerGy outlook special report 2015; international enerGy aGency, 9 rue de la fédération, 75739 paris cedex 15, june 2015. (iea-coal online 2011) http://WWW.coalonline.orG/site/coalonline/content/vieWer?loGdocid=81996&phydocid=7800&filename=7800 00023.html (Wca 2015) World coal association 2015; http://WWW.Worldcoal.orG/coal-the-environment/coal-use-theenvironment/improvinG-efficiencies/ (iea-etp 2014) enerGy technoloGy perspective – harnessinG electricities potential; iea may 2014.

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particularly high electric efficiencies can be achieved by combining gas turbines with a steam turbine in combined cycle mode. in a combined cycle gas turbine (ccGt) plant, a gas turbine generator produces electricity and the exhaust gases from the turbine are then used to make steam to generate additional electricity. the efficiency of modern ccGt power stations can be up to 60 (iea etp 2014). most new gas power plants built since the 1990s have been of this type. historically, a major driver of technology development for gasfired generation has been the quest for increased efficiency. however, the effort to raise power plant efficiency is not the only technical objective; other criteria, such as part-load efficiency, ramp rate, turndown ratio and start-up times, are important aspects for future flexible power generation systems as well (iea-etp 2014). during the transition period to 100% renewable flexible and quick starting gas turbines play an important role to integrate high shares of wind and solar.

in case of low gas prices, ccGt power stations are the cheapest option for electricity generation in many countries. capital costs have been substantially lower than for coal and nuclear plants and construction time shorter. 10.2 carbon reduction technologies and carbon capture and storage (ccs) Whenever a fossil fuel is burned, carbon dioxide (co 2) is produced. depending on the type of power plant, a large quantity of the gas will dissipate into the atmosphere and contribute to climate change. a hard coal power plant discharges 730 grams of carbon dioxide per kilowatt-hour if it is a (rare) ultra-supercritical coal plant, compared to 810g co 2 /kWh (iea-etp 2014) in an average modern coal plant. a modern gas power plant in comparison emits around about 350g co 2 /kWh. one method, currently under development, to mitigate the co 2 impact of fossil fuel combustion is called carbon capture and storage (ccs). it involves capturing co 2 from power plant smokestacks, compressing the captured gas for transport via pipeline or ship and pumping it into underground geological formations for permanent storage. While frequently touted as the solution to the carbon problem inherent in fossil fuel combustion, ccs for coal-fired power stations is unlikely to be ready for at least another decade. despite the ‘proof of concept’ experiments currently in progress, the technology remains unproven as a fully integrated process in relation to all of its operational components. suitable and effective capture technology has not been developed and is unlikely to be commercially available any time soon; effective and safe long-term storage on the scale necessary has not been demonstrated; and serious concerns attach to the safety aspects of transport and injection of co 2 into designated formations, while long term retention cannot reliably be assured. references 5 6

(iea tcep 2015); trackinG clean enerGy proGress 2015 - enerGy technoloGy perspectives 2015, iea input to the clean enerGy ministerial, june 2015. (teske – ccs 1) lead authors oWn calculation: 32.3 bn tonnes co 2 / 8760h = 3.6 bn tonnes /h

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deploying the technology in coal power plants is likely to double construction costs, increase fuel consumption by 1040%, consume more water, generate more pollutants and ultimately require the public sector to ensure that the co 2 stays where it has been buried. in a similar way to the disposal of nuclear waste, ccs envisages creating a scheme whereby future generations monitor in perpetuity the climate pollution produced by their predecessors. in october 2014, saskpower’s boundary dam unit 3 in canada became the world’s first commercial electricity generating unit with full co 2 capture. around 1 million tonnes of co 2 (mtco 2) per year – 90% of co 2 emissions from the unit – will be captured and stored underground through enhanced oil recovery (eor) (iea tcep 2015). 5 to put this in a global context: 1 million tonnes of co 2 storage is equal the global energy related co 2 emissions of about 17 minutes (teske ccs-1). 6 in 2014, energy-related co 2 emission added up to 32.3 billion tonnes of co 2. 10.2.1 carbon dioxide storage

in order to benefit the climate, captured co 2 has to be stored somewhere permanently. current thinking is that it can be pumped under the earth’s surface at a depth of over 3,000 feet into geological formations, such as saline aquifers. however, the volume of co 2 that would need to be captured and stored is enormous - a single coal-fired power plant can produce 7 million tonnes of co 2 annually. it is estimated that a single ‘stabilisation wedge’ of ccs (enough to reduce carbon emissions by 1 billion metric tonnes per year by 2050) would require a flow of co 2 into the ground equal to the current flow of coal out of the ground and in addition to the associated infrastructure to compress, transport and pump it underground. it is still not clear that it will be technically feasible to capture and bury this much carbon, both in terms of the number of storage sites and whether they will be located close enough to power plants. even if it is feasible to bury hundreds of thousands of megatonnes of co 2, there is no way to guarantee that storage locations will be appropriately designed and managed over the timescales required. the world has limited experience of storing co 2 underground; the longest running storage project at sleipner in the norwegian north sea began operation only in 1996. this is particularly concerning because as long as co 2 is present in geological sites, there is a risk of leakage. although leakages are unlikely to occur in well-characterised, managed and monitored sites, permanent storage stability cannot be guaranteed since tectonic activity and natural leakage over long timeframes are impossible to predict.

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sudden leakage of co 2 can be fatal. carbon dioxide is not itself poisonous but is contained (approx. 0.04 %) in the air we breathe. but as concentrations increase, it displaces the vital oxygen in the air; air with concentrations of 7 to 8% co 2 by volume causes death by suffocation after 30 to 60 minutes (Gpi-fh 2008). 7 there are also health hazards when large amounts of co 2 are explosively released. although the gas normally disperses quickly after leaking, it can accumulate in depressions in the landscape or closed buildings, since carbon dioxide is heavier than air. it is equally dangerous when it escapes more slowly and without being noticed in residential areas, for example in cellars below houses. the dangers from such leaks are known from natural volcanic co 2 degassing. Gas escaping at the lake nyos crater lake in cameroon, africa, in 1986 killed over 1,700 people. at least ten people have died in the lazio region of italy in the last 20 years as a result of co 2 being released.

greenpeace opposes any ccs efforts which leads to: • public financial support to ccs at the expense of funding renewable energy development and investment in energy efficiency. • stagnation of renewable energy, energy efficiency and energy conservation improvements. • inclusion of ccs in the kyoto protocol’s clean development mechanism (cdm) as it would divert funds away from the stated intention of the mechanism, and cannot be considered clean development under any coherent definition of this term. • promotion of this possible future technology as the only major solution to climate change, thereby leading to new fossil fuel developments – especially lignite and black coalfired power plants, and an increase in emissions in the short to medium term. 10.3 nuclear technologies

10.2.2 carbon storage and climate change targets

can carbon storage contribute to climate change reduction targets? in order to avoid dangerous climate change, global greenhouse gas emissions need to peak by between 2015 and 2020 and fall dramatically thereafter. however, power plants capable of capturing and storing co 2 are still being developed and won’t become a reality in a truly commercial scale for at least another decade, if ever. this means that even if ccs works, the technology would not make any substantial contribution towards protecting the climate before 2020. power plant co 2 storage will also not be of any great help in attaining the goal of at least an 80% greenhouse gas reduction by 2050 in oecd countries. even if ccs were to be available in 2020, most of the world’s new power plants will have just finished being modernised. all that could then be done would be for existing power plants to be retrofitted and co 2 captured from the waste gas flow. retrofitting power plants would be an extremely expensive exercise. ‘capture ready’ power plants are equally unlikely to increase the likelihood of retrofitting existing fleets with capture technology. the conclusion reached in the energy revolution scenario is that renewable energy sources are already available, in many cases cheaper, and lack the negative environmental impacts associated with fossil fuel exploitation, transport and processing. it is renewable energy together with energy efficiency and energy conservation – and not carbon capture and storage – that has to increase worldwide so that the primary cause of climate change – the burning of fossil fuels like coal, oil and gas – is stopped.

Generating electricity from nuclear power involves transferring the heat produced by a controlled nuclear fission reaction into a conventional steam turbine generator. the nuclear reaction takes place inside a core and surrounded by a containment vessel of varying design and structure. heat is removed from the core by a coolant (gas or water) and the reaction controlled by a moderating element or “moderator”. across the world over the last two decades there has been a general slowdown in building new nuclear power stations because of concern about a possible nuclear accident (following the events at three mile island, chernobyl, monju and fukushima) and increased scrutiny of economics and environmental factors, such as waste management and radioactive discharges. nuclear reactor designs: evolution and safety issues

by mid-2015 there were 391 nuclear power reactors operating in 31 countries around the world. nuclear plants are commonly divided into four generations. there are no clear definitions of design categories (scheider/froggatt 2015): 8 generation i: prototype commercial reactors developed in the 1950s and 1960s as modified or enlarged military reactors, originally either for submarine propulsion or plutonium production. generation ii: mainstream reactor designs in commercial operation worldwide.

references 7 8

(Gpi-fh 2008) “false hope”; Greenpeace international; emily rochon et. al.; may 2008; Greenpeace international; ottho heldrinGstraat 5; 1066 aZ amsterdam; the netherlands. (scheider/froGGatt 2015) the World nuclear industry – status report 2015; paris, london, july 2015; © a mycle schneider consultinG project.

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generation iii: new generation reactors now being built. generation iii+ and iv: reactors developed or significantly modified after the chernobyl disaster. Generation iii+ reactors include the so-called advanced reactors, three of which are already in operation in japan, with more under construction or planned. about 20 different designs are reported to be under development, 9 most of them ‘evolutionary’ designs developed from Generation ii reactor types with some modifications, but without introducing drastic changes. some of them represent more innovative approaches. according to the World nuclear association, reactors of Generation iii are characterised by the following: • a standardised design for each type to expedite licensing, reduce capital cost and construction time • a simpler and more rugged design, making them easier to operate and less vulnerable to operational upsets

• higher availability and longer operating life, typically 60 years • reduced possibility of core melt accidents • minimal effect on the environment • higher burn-up to reduce fuel use and the amount of waste

• the epr has fewer redundant pathways in its safety systems than a German Generation ii reactor. several other modifications are hailed as substantial safety improvements, including a ‘core catcher’ system to control a meltdown accident. nonetheless, in spite of the changes being envisaged, there is no guarantee that the safety level of the epr actually represents a significant improvement. in particular, reduction of the expected core melt probability by a factor of ten is not proven. furthermore, there are serious doubts as to whether the mitigation and control of a core melt accident with the core catcher concept will actually work. the World nuclear association (Wna) claims that: “newer advanced reactors [Generation iii+] now being built have simpler designs which reduce capital cost. they are more fuel efficient and are inherently safer. in more detail, it lists some of the design characteristics of which the most relevant to this analysis are (schneider/froggatt 2015): • a standardized design for each type to expedite licensing, reduce capital cost and reduce construction time, • a simpler and more rugged design, making them easier to operate and less vulnerable to operational upsets, • further reduced possibility of core melt accidents,

• burnable absorbers (‘poisons’) to extend fuel life

• substantial grace period, so that following shutdown the plant requires no active intervention for (typically) 72 hours,

to what extent these goals address issues of higher safety standards, as opposed to improved economics, remains unclear.

• resistance to serious damage that radioactivity after an aircraft impact.

of the new reactor types, the european pressurised Water reactor (epr) has been developed from the most recent Generation ii designs to start operation in france and finland (schneider/froggatt 2015). its stated goals are to improve safety levels - in particular to reduce the probability of a severe accident by a factor of ten, achieve mitigation from severe accidents by restricting their consequences to the plant itself, and reduce costs. compared to its predecessors, however, the epr displays several modifications which constitute a reduction of safety margins, including: • the volume of the reactor building has been reduced by simplifying the layout of the emergency core cooling system, and by using the results of new calculations which predict less hydrogen development during an accident. • the thermal output of the plant has been increased by 15% relative to existing french reactors by increasing core outlet temperature, letting the main coolant pumps run at higher capacity and modifying the steam generators.

references 9

(iaea 2004; Wno 2004)

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price rises occur throughout the period from project announcement to operation. for example, in 2003, the french industry ministry estimated that construction costs for an epr would be just over €1 billion (us$1.2 billion) per reactor. the price tag had tripled by the time the contract was signed for the flamanville plant in 2007, and by 2012, the estimated cost had reached €8.5 billion (us$10.6 billion) (schneider/froggatt 2015). finally, Generation iv reactors are currently being developed with the aim of commercialisation in 20-30 years. 10.4 renewable power heating technologies

technologies

and

renewable energy covers a range of natural sources which are constantly renewed and therefore, unlike fossil fuels and uranium, will never be exhausted. most of them derive from the effect of the sun and moon on the earth’s weather patterns. they also produce none of the harmful emissions and pollution associated with ‘conventional’ fuels. although hydroelectric power has been used on an industrial scale since the middle of the last century, the serious exploitation of other renewable sources has a more recent history.

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box 10.1 | definition of renewable energy

geothermal field at a faster rate than heat flows can replenish it. on the other hand, the rate of utilization of direct solar energy has no bearing on the rate at which it reaches the earth. fossil fuels (coal, oil, natural gas) do not fall under this definition, as they are not replenished within a time frame that is short relative to their rate of utilization.”

“renewable energy is any form of energy from solar, geophysical or biological sources that is replenished by natural processes at a rate that equals or exceeds its rate of use. re is obtained from the continuing or repetitive ﬂows of energy occurring in the natural environment and includes resources such as biomass, solar energy, geothermal heat, hydropower, tide and waves and ocean thermal energy, and wind energy. however, it is possible to utilize biomass at a greater rate than it can grow, or to draw heat from a

IPCC definition for renewable energy (Source IPCC, Special Report Renewable Energy /SRREN Renewables for Power Generation.

figure 10.1 | illustrative system for energy production and use illustrating the role of re along with other production options

10 ELE CTRICITY CONS UMPTION

E N E RG Y C O N V ER S I O N R E NE WA BL E

RESIDENTIAL

E L EC T R I C I T Y D I ST R I B UT I O N

ECONOMIC P R O D U C T IV I T Y e[r] oil demand C O MM E R C IA L

R E C OV E RY & E X TR A CT ION

E L EC T R I C T R AN S P O R TAT I ON

N UC L E A R

GHG

FUE L COMBUS TION RAW MATER I A L MOVEME NT

FOSSIL

P R OD U C T C O N V E R SI O N

T R AN SP O R T O F LI Q U I D FUEL

G A SO L I N E / E TH A N O L

J E T FU E L

GHG

T R AN S P O RTAT I ON P R O D U C T IV I T Y

GHG

T R AN S P O RTAT I ON P R O D U C T IV I T Y

G D I E SE L FU E L

B IO M A S S FO R E NE R G Y

B U N K E R FU E L

A G R IC U LT UR E , F O R ES T RY, R ES ID UES

GHG

CO2

GHG

BIOMASS CO-PRODUCT

source ipcc-srren 2012

C O -P R O D UC T

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10.4.1 solar power (photovoltaics)

there is more than enough solar radiation available all over the world to satisfy a vastly increased demand for solar power systems. the sunlight which reaches the earth’s surface is enough to provide 7,900 times as much energy as we can currently use. on a global average, each square metre of land is exposed to enough sunlight to produce 1,700 kWh of power every year. the average irradiation in europe is about 1,000 kWh per square metre and 1,800 kWh in the middle east.

photovoltaic (pv) technology involves the generation of electricity from light. photovoltaic systems contain cells that convert sunlight into electricity. inside each cell there are layers of a semi-conducting material. light falling on the cell creates an electric field across the layers, causing electricity to flow. the intensity of the light determines the amount of electrical power each cell generates. a photovoltaic system does not need bright sunlight in order to operate. it can also generate some electricity on cloudy and rainy days from diffuse sunlight.

conditions, allowing comparison between different modules. in central europe a 3 kWp rated solar electricity system, with a surface area of approximately 27 square metres, would produce enough power to meet the electricity demand of an energy conscious household. there are several different pv technologies and types of installed system. pv systems can provide clean power for small or large applications. they are already installed and generating energy around the world on individual homes, housing developments, offices and public buildings. today, fully functioning solar pv installations operate in both built environments and remote areas where it is difficult to connect to the grid or where there is no energy infrastructure. pv installations that operate in isolated locations are known as stand-alone systems. in built areas, pv systems can be mounted on top of roofs (known as building adapted pv systems – or bapv) or can be integrated into the roof or building facade (known as building integrated pv systems – or bipv).

the most important parts of a pv system are the cells which form the basic building blocks, the modules which bring together large numbers of cells into a unit, and, in some situations, the inverters used to convert the electricity generated into a form suitable for everyday use. When a pv installation is described as having a capacity of 3 kWp (peak), this refers to the output of the system under standard testing

modern pv systems are not restricted to square and flat panel arrays. they can be curved, flexible and shaped to the building’s design. innovative architects and engineers are constantly finding new ways to integrate pv into their designs, creating buildings that are dynamic, beautiful and provide free, clean energy throughout their life.

figure 10.2 | example of the photovoltaic effect

figure 10.3 | photovoltaic technology

LOAD CURRENT 2

PHOTONS JUNCTION

ELECTRON FLOW N-TYPE SILICON P-TYPE SILICON ‘HOLE’ FLOW

3 4 5

source epia.

232

source epia.

1. 2. 3. 4. 5. 6. 7.

liGht (photons) front contact Grid anti-reflection coatinG n-type semiconductor boarder layout p-type semiconductor back contact

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10.4.2 pv cells and modules

10.4.3 pv systems

crystalline silicon technology: crystalline silicon cells are made from thin slices cut from a single crystal of silicon (mono crystalline) or from a block of silicon crystals (polycrystalline or multi crystalline). this technology is the most common, representing about 80% of the market today. in addition, it also exists in the form of ribbon sheets (hoffmann /teske 2012). 10

the key parts of a solar energy generation system are:

thin film technology: thin film modules are constructed by

depositing extremely thin layers of photosensitive materials onto a substrate such as glass, stainless steel or flexible plastic. the latter opens up a range of applications, especially for building integration (roof tiles) and endconsumer purposes. four types of thin film modules are commercially available at the moment: amorphous silicon, cadmium telluride, copper indium/Gallium diselenide/disulphide and multi-junction cells. other emerging cell technologies (at the development or early commercial stage): these include concentrated photovoltaic,

consisting of cells built into concentrating collectors that use a lens to focus the concentrated sunlight onto the cells, and organic solar cells, whereby the active material consists at least partially of organic dye, small, volatile organic molecules or polymer. cells are connected to form larger units called modules. thin sheets of eva (ethyl vinyl acetate) or pvb (polyvinyl butyral) are used to bind cells together and provide weather protection. the modules are normally enclosed between a transparent cover (usually glass) and a weatherproof backing sheet (typically made from a thin polymer). modules can be framed for extra mechanical strength and durability. thin film modules are usually encapsulated between two sheets of glass, so a frame is not needed (epia-2011). 11

table 10.1 | typical type and size of applications per market segment type of application

residential

commercial

industrial

utility- scale

10 kWp - 100 kWp

100 kWp - 1 mWp

> 1 mWp

yes

10 kWp

Ground-mounted

yes

roof-top

yes

inteGrated to facade/roof

yes

source ?

references 10 11

• photovoltaic modules to collect sunlight • an inverter to transform direct current (dc) to alternate current (ac) • a set of batteries for stand-alone pv systems • support structures to orient the pv modules toward the sun. the system components, excluding the pv modules, are referred to as the balance of system (bos) components. industrial and utility-scale power plants

large industrial pv systems can produce enormous quantities of electricity at a single location. such power plants have outputs ranging from hundreds of kilowatts (kW) to hundreds of megawatts (mW). the solar panels for industrial systems are usually mounted on frames on the ground. however, they can also be installed on large industrial buildings, such as warehouses, airport terminals and railways stations. the system can make double use of an urban space and put electricity into the grid where energy-intensive consumers are located. residential and commercial systems grid connected

Grid connected arrays are the most popular type of solar pv systems for homes and businesses in the developed world. connected to the local grid, they allow any excess power produced to be sold to the utility. When solar energy is not available, electricity can be drawn from the grid. an inverter is used to convert the dc power produced by the system to ac power for running normal electrical equipment. this type of pv system is referred to as being ‘on-grid.’ a ‘Grid support’ system can be connected to the local grid along with a backup battery. any excess solar electricity produced after the battery has been charged is then sold to the grid. this system is ideal for use in areas of unreliable power supply. stand - alone , off - grid systems

off-grid pv systems have no connection to a grid. an off-grid system usually has batteries, so power can still be used at night or after several days of low sun. an inverter is needed to convert the dc power generated into ac power for use in appliances. typical off-grid applications include: • off-grid systems for rural electrification Grid typical off-grid installations bring electricity to remote areas or villages in developing countries. they can be small home systems, which cover a household’s basic electricity needs, or larger solar mini-grids, which provide enough power for several homes, a community or small business use.

(hoffmann/teske 2012) preparation for epia/Greenpeace solarGeneration report series(edition i – vi). (epia 2011) solarGeneration 6 – epia-Greenpeace report; european photovoltaic industry association (epia); Gpi, brussels / amsterdam; 2011.

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• off-grid industrial applications off-grid industrial systems are used in remote areas to power repeater stations for mobile telephones (enabling communications), traffic signals, marine navigational aids, remote lighting, highway signs and water treatment plants. both full pv and hybrid systems are used. hybrid systems are powered by the sun when it is available and by other fuel sources during the night and extended cloudy periods. off-grid industrial systems provide a cost-effective way to bring power to areas very far from existing grids. the high cost of installing cabling makes off-grid solar power an economical choice. • consumer goods pv cells are now found in many everyday electrical appliances such as watches, calculators, toys, and battery chargers (as for instance embedded in clothes and bags). services such as water sprinklers, road signs, lighting and telephone boxes also often rely on individual pv systems.

• hybrid systems a solar power system can be combined with another source of power – such as a biomass generator, a wind turbine or diesel generator - to ensure a consistent supply of electricity. a hybrid system can be grid-connected, standalone or grid-supported.

10.4.4 concentrating solar power (csp)

the majority of the world’s electricity today—whether generated by coal, gas, nuclear, oil or biomass—comes from creating a hot ﬂuid. concentrating solar power (csp) technologies produce electricity by concentrating direct-beam solar irradiance to heat a liquid, solid or gas that is then used in a downstream process for electricity generation. csp simply provides an alternative heat source. csp uses direct sunlight, called ‘beam radiation’ or direct normal irradiation (dni) – sunlight not dispersed by clouds, fumes or dust in the atmosphere. this sunlight reaches the earth’s surface in parallel beams for concentration. suitable sites need to get a lot of this direct sun - at least 2,000 kilowatt-hours (kWh) per square metre annually and the best sites receive more than 2,800 kWh/m2/year. in these regions, one square kilometre of land is enough to generate as much as 100-130 gigawatt hours (GWh) of solar electricity per year using solar thermal technology. thus, csp plants, also called solar thermal power plants, produce electricity in much the same way as conventional power stations. they obtain their energy input by concentrating solar radiation and converting it to high temperature steam or gas to drive a turbine or motor engine. large mirrors concentrate sunlight into a single line or point.

figure 10.4 | different configurations of solar power systems

source epia 2011

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the heat created there is used to generate steam. this hot, highly pressurised steam is used to power turbines which generate electricity. in sun-drenched regions, csp plants can guarantee a large proportion of electricity production. this technology builds on much of the current know-how on power generation in the world today. it will beneﬁt from on-going advances in solar concentrator technology and as improvements continue to be made in steam and gas turbine cycles.

linear fresnel systems

collectors resemble parabolic troughs, with a similar power generation technology, using long lines of flat or nearly flat fresnel reflectors to form a field of horizontally mounted flat mirror strips, collectively or individually tracking the sun. these are cheaper to install than trough systems but not as efficient. there is one plant currently in operation in europe: puerto errado (2 mW).

some of the advantages of csp: • it can integrate thermal storage for peaking loads (less than one hour) and intermediate loads (three to six hours); • it can provide industrial process heat • it can be used of desalination to produce drinking water • it has modular and scalable components; types of csp systems

all systems require four main elements: a concentrator, a receiver, some form of transfer medium or storage, and power conversion. many different types of system are possible, including combinations with other renewable and non-renewable technologies, but there are four main groups of solar thermal technologies. this whole subchapter is based on a technical paper of the european solar thermal electricity association (estela 2015): 12 parabolic trough

parabolic trough plants use rows of parabolic trough collectors, each of which reflect the solar radiation into an absorber tube. the troughs track the sun around one axis, with the axis typically being oriented north-south. synthetic oil circulates through the tubes, heating up to approximately 400°c. the hot oil from numerous rows of troughs is passed through a heat exchanger to generate steam for a conventional steam turbine generator to generate electricity. some of the plants under construction have been designed to produce power not only during sunny hours but also to store energy, allowing the plant to produce an additional 7.5 hours of nominal power after sunset, which dramatically improves their integration into the grid. molten salts are normally used as storage fluid in a hot-and-cold two-tank concept. plants in operation in europe: andasol 1 and 2 (50 mW +7.5 hour storage each); puertollano (50 mW); alvarado (50 mW) and extresol 1 (50 mW + 7.5 hour storage). land requirements are of the order of 2 km 2 for a 100-mWe plant, depending on the collector technology and assuming no storage is provided.

references 12

(estela 2015) concentrated solar poWer outlook 2015; european solar thermal electric association; brussels september 2015.

central receiver or solar tower

central receivers (or “power towers”) are point-focus collectors that are able to generate much higher temperatures than troughs and linear fresnel reﬂectors. this technology uses a circular array of mirrors (heliostats) where each mirror tracks the sun, reflecting the light onto a ﬁxed receiver on top of a tower. temperatures of more than 1,000°c can be reached. a heat-transfer medium absorbs the highly concentrated radiation reflected by the heliostats and converts it into thermal energy to be used for the subsequent generation of superheated steam for turbine operation. to date, the heat transfer media demonstrated include water/steam, molten salts, liquid sodium and air. if pressurised gas or air is used at very high temperatures of about 1,000°c or more as the heat transfer medium, it can even be used to directly replace natural gas in a gas turbine, thus making use of the excellent efficiency (60%+) of modern gas and steam combined cycles. after an intermediate scaling up to 30 mW capacity, solar tower developers now feel confident that grid-connected tower power plants can be built up to a capacity of 200 mWe solar-only units. use of heat storage will increase their flexibility. although solar tower plants are considered to be further from commercialisation than parabolic trough systems, they have good longer-term prospects for high conversion efficiencies. projects are being developed in spain, south africa and australia. parabolic dish

a dish-shaped reflector is used to concentrate sunlight on to a receiver located at its focal point. the receiver moves with the dish. the concentrated beam radiation is absorbed into the receiver to heat a fluid or gas to approximately 750°c. this is then used to generate electricity in a small piston, stirling engine or micro turbine attached to the receiver. dishes have been used to power stirling engines up to 900°c, and also for steam generation. the largest solar dishes have a 485-m 2 aperture and are in research facilities or demonstration plants. currently the capacity of each stirling engine is small — in the order of 10 to 25 kWelectric. there is now signiﬁcant operational experience with dish/stirling engine systems and the technology has been under development for many years, with advances in dish structures, high-temperature receivers, use of hydrogen as the circulating working ﬂuid, as well as some experiments 235

world energy [r]evolution a sustainable world energy outlook

with liquid metals and improvements in stirling engines â&#x20AC;&#x201D; all bringing the technology closer to commercial deployment. although the individual unit size may only be of the order of tens of kWe, power stations having a large capacity of up to 800 mWe have been proposed by aggregating many modules. because each dish represents a stand-alone electricity generator, from the perspective of distributed generation there is great ďŹ&#x201A;exibility in the capacity and rate at which units are installed. however, the dish technology is less likely to integrate thermal storage. the potential of parabolic dishes lies primarily for decentralised power supply and remote, stand-alone power systems. projects are currently planned in the united states, australia and europe. csp system components

in addition to the different types of solar reflector systems, a csp power plant has power generation equipment like what is used in gas power plants; increasingly, a thermal storage unit is also installed. the output of a csp power plant is power and different levels of heat which can be used for industrial process heat, for the desalination of water, etc.

10.4.5 csp - thermal storage

thermal energy storage integrated into a system is an important attribute of csp. until recently, this has been primarily for operational purposes, providing 30 minutes to 1 hour of fullload storage. this eases the impact of thermal transients such as clouds on the plant, assists start-up and shut-down, and provides beneďŹ ts to the grid. trough plants are now designed for 6 to 7.5 hours of storage, which is enough to allow operation well into the evening when peak demand can occur and tariffs are high. to provide solar electricity after sunset with csp, thermal energy is stored in very large quantities. thermal energy storage (tes) systems are an integral part of a csp power plant, allowing eliminating short term variations of electricity production: the thermal energy collected by the solar field is stored for conversion to electricity later in the day. storage can adapt the profile of power produced throughout the day to demand and can increase the total power output of a plant with given maximum turbine capacity by storing excess energy of a larger solar field before it is used in the turbine. eventually the plant can be operated nearly at 100% capacity factor as a base load plant in appropriate locations.

figure 10.5 | csp technologies: parabolic trough, central receiver/solar tower and parabolic dish

parabolicTROUGH trough PARABOLIC

central receiver CENTRAL RECEIVER

parabolicDISH dish PARABOLIC

5 2

1. 2. 3. 4. 5. 6.

source estela 2015

236

absorber tube reflector central receiver heliostats receiver/enGine reflector

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thermal storage has been used in 40% of spanish plants since 2010 and is almost included in every new plant today. a number of 5 to 10 hours storage, depending on the dni is an average. the iea reports that “when thermal storage is used to increase the capacity factor, it can reduce the levelised cost of solar thermal electricity (lcoe). thermal storage also has remarkable “return” efficiency, especially when the storage medium is also used as heat transfer fluid. it may then achieve 98% return efficiency – i.e., energy losses are limited to about 2%. there are 3 categories of storage media that can be used in csp plant but their maturity degree is different (estela 2015): • advanced sensible heat storage systems : such system are in most of the state-of-the-art csp plants, with a “two-tank molten salt storage” (two tanks with molten salts at different temperature levels). the development of new storage mediums with improved thermal stability, such as molten salt mixtures will allow higher temperatures to be attained. higher temperatures allow for increased energy density within the tes and hence lower the specific investment costs for the system. improvements to tes systems would have the potential to reduce capex while improving efficiency.

• cost-effective latent heat storage systems : latent heat storage has not been implemented in commercial ste plants yet, but several research project support the introduction and use of phase changing materials in tes technologies. the use of latent heat storage offers new possibilities for dsG helping in achieving cost competitiveness with sensible heat technologies. • thermochemical storage systems : to date, there are no known commercial systems for thermochemical tes in ste plants. research into the application this technology started 40 years ago. development projects assume potentials in energy density up to 10 times higher than a comparable sensible heat tes (estela 2015).

figure 10.6 | principle of csp systems

3 5 2

1. parabolic mirrors (concentratinG solar collector field). heat transfer fluid is heated directly by the sun’s rays.

4. condenser. converts the steam back into Water and the process beGins aGain.

2. heat exchangers.

5. steam turbine & generator. inside the steam expands and spins the turbine, GeneratinG electricity that passes throuGh a transformer before beinG feed into the Grid.

3. thermal storage tanks.

source estela 2015.

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world energy [r]evolution a sustainable world energy outlook

10.4.6 wind power

Wind energy has grown faster than all other electricity sources in the last 20 years, and turbine technology has advanced sufficiency that a single machine can have a capacity of 7 megawatt. in europe, wind farms are generally well integrated into the environment and accepted by the public. smaller models can produce electricity for areas that are not connected to a central grid, through use of battery storage.

main shaft and main bearings, gearbox, generator and control system are contained within a housing called the nacelle. as turbine size has increased over time, turbine output is controlled by pitching (i.e., rotating) the blades along their long axis.14 reduced cost of power electronics allowed for variable speed wind turbine operation, which helps maintain production in variable and gusty winds, keeps large wind power plants generating during electrical faults, and provides reactive power.

Wind speeds and patterns are good enough for this technology on all continents, on both coastlines and inland. the wind resource out at sea is particularly productive and is now being harnessed by offshore wind parks with foundations embedded in the ocean floor.

modern wind turbines typically operate at variable speeds using full-span blade pitch control. over the past 30 years, the average wind turbine size has grown signiﬁcantly (figure 9), with most onshore wind turbines installed globally in 2014 having a rated capacity of 3.5 to 7,5 mW; the average size of turbines installed in 2014 was at around 2.5 – 3.0 mW.

wind turbine design

as of 2015, wind turbines used on land typically have 80 to 120m tall towers, with rotors between 80 to 125 m in diameter. the average tower installed in 2014 in Germany for example was 93 m tall (statistica 2015).15 some commercial machines have diameters and tower heights above 125 m, and even larger models are being developed. modern turbines operate spin at 12 to 20 revolutions per minute (rpm), much slower than the models from the 1980s models, which spun at 60 rpm. modern rotors are slower, less visually disruptive and less noisy.

modern wind technology is available for low and high wind speeds, and in a variety of climates. a variety of onshore wind turbine conﬁgurations have been investigated, including both horizontal and vertical axis designs (see figure 4 ). the horizontal axis design dominates, and most designs now centre on the three-blade, upwind rotor; locating the turbine blades upwind of the tower prevents the tower from blocking wind ﬂow onto the blades and producing extra aerodynamic noise and loading (eWea 2008). 13 the blades are attached to a hub and main shaft, which transfers power to a generator, sometimes via a gearbox (depending on design). the electricity output is channelled down the tower to a transformer and eventually into the local grid. the

onshore wind turbines are typically grouped together into wind power plants, with between 5- 300 mW generating capacity, and are sometimes also called wind farms. turbines have been getting larger to help reduce the cost of generation (reach better quality wind), reduce investment per unit of capacity and reduce operation and maintenance costs (eWea 2014). 16

figure 10.7 | ewea early wind turbine designs horizontal axis turbines

vertical axis turbines

references

source south et.al. 1983 / eWea 2008.

13 14 15 16

238

(eWea 2009) Wind enerGy – the facts; european Wind enerGy association; brussels/belGium ; http://WWW.Wind-enerGy-the-facts.orG). eWea 2009. (statistica 2015); online statistical research tool; http://WWW.statista.com/statistics/263905/evolutionof-the-hub-heiGht-of-German-Wind-turbines/. (eWea 2014) Wind enerGy scenarios for 2020; european Wind enerGy association; july 2014; WWW.eWea.orG.

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for turbines in land, there will be engineering and logistical constraints to size because the components have to travel by road.

need for new, long-distance, land-based transmission infrastructure that wind farms on land can require.18

modern wind turbines have nearly reached their theoretical maximum (0.59) of aerodynamic efﬁciency, measured by the coefﬁcient of performance (0.44 in the 1980s to about 0.50 by the mid-2000s).

there is considerable interest in offshore wind energy technology in the eu and, increasingly, in other regions such as china, japan and north america, despite the typically higher costs relative to onshore wind energy, because of its advantage to supply large coastal cities and/or industry.

offshore wind energy technology

offshore wind turbines built between 2009 and 2014 typically have nameplate capacity ratings of 2 to 5 mW, and larger turbines are under development. offshore wind farms are installed in groups of 50 to 100 turbines with total capacities in the low to medium hundred megawatt capacity, and often installed in water between 10 and 20 m deep. distance to shore has is mostly less than 20 km, but average distance has increased over time. 19 offshore wind is likely to be installed at greater depths, and the larger turbines (5 to 10mW or larger) as experience is gained and for greater economies of scale.

by the end of 2014, the existing offshore market made up just 2.4% of the world’s land-based installed wind capacity; however, the potential at sea is driving the latest developments towards large turbine sizes. Wind technology currently develops for two different markets: offshore and sites of high wind resources; and onshore sites of moderate resources which requires different technical concepts. the first offshore wind power plant was built in 1991 in denmark, consisting of eleven 450 kW wind turbines. in 2014 1,713 mW of new offshore capacity was added, bringing the total to 8,759 megawatts (GWec 2015). 17 by going offshore, wind energy can make use stronger winds and provide clean energy to countries where there is less technical potential for land-based wind energy development and where it would conflict with other land uses. there is less ‘shear’ near hub height with offshore wind. Greater economies of scale result from large turbines that can be transported by ship and from larger power plants. offshore wind farms also reduce the

offshore wind turbine technology has been very similar to onshore designs, with some structural modifications and with special foundations. 20 other design features include marine navigational equipment and monitoring and infrastructure to minimise expensive servicing. by 2015, the offshore wind industry started moving into the commercialization phase; further cost reductions are likely. the German offshore Wind industry expects that, in stable market conditions, the costs of offshore wind power can decrease by up to 39 % by 2023 (GoWef 2014). 21

figure 10.8 | basic component of wind turbines without gearboxes

figure 10.9 | growth of size of typical commercial wind turbines 20,000kW

5 6 7

PITCH

h: HUB HEIGHT D: DIAMETER OF THE ROTOR

ROTOR DIAMETER SWEPT AREA OF BLADES

5,000kW

HUB HEIGHT

1,800kW

750kW

75kW

source eWea 2008.

source eWea 2008/2014.

references

19 20 21

17 18

(GWec, 2015) Global Wind report 2014 – annual market update; Global Wind enerGy council, brussels/belGium, WWW.GWec.net ; march 2015. carbon trust, 2008b; snyder and kaiser, 2009b; tWidell and Gaudiosi, 2009.

Future H: 180m/D: 250m

2010-? H: 125m/D: 125m

2005-10 H: 80m/D: 80m

TRANSFORMER

1995-00 H: 50m/D: 50m

ROTOR BLADE BLADE ADJUSTMENT NACELL ROTOR SHAFT ANEMOMETOR GENERATOR SYSTEM CONTROL LIFT INSIDE THE TOWER

1980-90 H: 20m/D: 17m

1. 2. 3. 4. 5. 6. 7. 8.

(eWea, 2010a). musial, 2007; carbon trust, 2008b. (GoWef 2014); cost reduction potentials of offshore Wind poWer in Germany; proGnos / fichtner, commissioned by: the German offshore Wind enerGy foundation; andreas WaGner; oldenburGer str. 65; 26316 varel; Germany; WWW.offshorestiftunG.de

239

world energy [r]evolution a sustainable world energy outlook

the next step – floating offshore wind

in order to unlock the full potential of offshore wind, areas with water depth greater than 50 meters must be opened for this technique. large cities in asia and latin america are often close to the sea, and offshore wind farms can potentially supply mega-cities with electricity and/or the production of syn-fuels in the future.

the concept of a floating wind turbine has existed since the early 1970s, but the industry only started researching it in the mid-1990s. in 2008, blue h technologies installed the first test floating wind turbine off the italian coast. the turbine had a rated capacity of 80 kW; after a year of testing and data collection, it was decommissioned. a year later, the poseidon 37 project followed, a 37m-wide wave energy plant and floating wind turbine foundation tested at donG’s offshore wind farm at onsevig. in 2009, statoil installed the world’s first large scale grid connected floating wind turbine, hywind, in norway, with a 2.3 mW siemens turbine. the second large scale floating system, Windfloat, developed by principle power in partnership with edp and repsol, was installed off the portuguese coast in 2011. equipped with a 2 mW vestas wind turbine, the installation started producing energy in 2012 (eWea 7-2013). 22

figure 10.10 | offshore wind foundation technologies

source eWea-7-2013.

references 22

(eWea-7-2013); deep Water - the next step for offshore Wind enerGy; european Wind enerGy association july 2013; isbn: 978-2-930670-04-1.

240

2011 was the best year on record for deep offshore development with two floating substructures tested, seatwirl and sWay, in addition to the grid connected Windfloat project. by the end of 2013, offshore wind farms used three main types of deep offshore foundations, adapted from the offshore oil and gas industry (eWea 7-2013): • spar buoy: a very large cylindrical buoy stabilizes the wind turbine using ballast. the centre of gravity is much lower in the water than the centre of buoyancy. Whereas the lower parts of the structure are heavy, the upper parts are usually empty elements near the surface, raising the centre of buoyancy. the hywind concept consists of this slender, ballast-stabilised cylinder structure. • tension leg platform: a very buoyant structure is semi submerged. tensioned mooring lines are attached to it and anchored on the seabed to add buoyancy and stability. • semi-submersible: combining the main principles of the two previous designs, a semi submerged structure is added to reach the necessary stability. Windfloat uses this technology.

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10.4.7 biomass energy

10.4.8 biomass technology

biomass is a broad term used to describe material of recent biological origin that can be used as a source of energy. it includes wood, crops, algae and other plants as well as agricultural and forest residues. biomass can be used for a variety of end uses: heating, electricity generation or as fuel for transportation. the term ‘bioenergy’ is used for biomass energy systems that produce heat and/or electricity; ‘biofuels’, for liquid fuels used in transport. biodiesel and bioethanol manufactured from various crops have become increasingly common as vehicle fuels, especially as the cost of oil has risen.

a number of processes can be used to convert energy from biomass: thermochemical processes (direct combustion of solids, liquids or a gas via pyrolysis or gasification) and biological systems, (decomposition of solid biomass to liquid or gaseous fuels by processes such as anaerobic digestion and fermentation).

biological power sources are renewable, easily stored, and, if sustainably harvested, co 2 neutral. the gas emitted during their transfer into useful energy is balanced by the carbon dioxide absorbed when they were growing plants. bioenergy for power generation

electricity generating biomass power plants work just like natural gas or coal power stations, except that the fuel must be processed before it can be burned. these power plants are generally not as large as coal power stations because their fuel supply needs to grow as near as possible to the plant. heat generation from biomass power plants can result either from utilising a combined heat and power (chp) system, piping the heat to nearby homes or industry, or through dedicated heating systems. small heating systems using specially produced pellets made from waste wood, for example, can be used to heat single family homes instead of natural gas or oil.

figure 10.11 | biogas technology

direct combustion

direct biomass combustion is the most common way of converting biomass into energy for both heat and electricity, accounting for over 90% of biomass generation. combustion processes are well understood; in essence, when carbon and hydrogen in the fuel react with excess oxygen to form co 2 and water and release heat. in rural areas, many forms of biomass are burned for cooking. Wood and charcoal are also used as a fuel in industry. a wide range of existing commercial technologies are tailored to the characteristics of the biomass and the scale of their applications (iea bio-2009). the technologies types are fixed bed, fluidised bed or entrained flow combustion. in fixed bed combustion, such as a grate furnace, air first passes through a fixed bed for drying, gasification and charcoal combustion. the combustible gases produced are burned after the addition of secondary air, usually in a zone separated from the fuel bed. in fluidised bed combustion, the primary combustion air is injected from the bottom of the furnace with such high velocity that the material inside the furnace becomes a seething mass of particles and bubbles. entrained flow combustion is suitable for fuels available as small particles, such as sawdust or fine shavings, which are pneumatically injected into the furnace. gasification

thermochemical processes

biomass fuels are increasingly being used with advanced conversion technologies, such as gasification systems, which are more efficient than conventional power generation. biomass gasification occurs when a partial oxidation of biomass happens upon heating, producing a combustible gas mixture (called producer gas or fuel gas) rich in co and hydrogen (h2) that has an energy content of 5 to 20 mj/nm3 (depending on the type of biomass and whether gasification is conducted with air, oxygen or through indirect heating). this energy content is roughly 10 to 45% of the heating value of natural gas (ipcc srren 2011). 23

1. HEATED MIXER 2. CONTAINMENT FOR FERMENTATION 3. BIOGAS STORAGE 4. COMBUSTION ENGINE 5. GENERATOR 6. WASTE CONTAINMENT

references 23

(ipcc-ar5-spm) international panel on climate chanGe – 5th assessment report; climate chanGe 2014, summary fotr policy makers; http://ipcc.ch/pdf/assessment-report/ar5/syr/ar5_syr_final_spm.pdf

241

world energy [r]evolution a sustainable world energy outlook

fuel gas can then be upgraded to a higher-quality gas mixture called biomass synthesis gas or syngas (faaij 2006). 24 a gas turbine, boiler or steam turbine can be used to employ unconverted gas for electricity co-production. coupled with electricity generators, syngas can be used as a fuel in place of diesel in suitably designed or adapted internal combustion engines. most commonly available gasifiers use wood or woody biomass, specially designed gasifiers can convert non-woody biomass materials (yokoyama and matsumura 2008). 25 compared to combustion, gasification is more efficient, providing better controlled heating, higher efficiencies in power production and the possibility for coproducing chemicals and fuels (kirkels and verbong 2011). 26 Gasification can also decrease emission levels compared to power production with direct combustion and a steam cycle. pyrolysis

pyrolysis is the thermal decomposition of biomass occurring in the absence of oxygen (anaerobic environment) that produces a solid (charcoal), a liquid (pyrolysis oil or bio-oil) and a gas product. the relative amounts of the three coproducts depend on the operating temperature and the residence time used in the process. lower temperatures produce more solid and liquid products and higher temperatures more biogas. heating the biomass feedstock to moderate temperatures (450Â°c to 550Â°c) produce oxygenated oils as the major products (70 to 80%), with the remainder split between a bio char and gases (iea bio-2009).

references 24 25 26

(faaij 2006). (yokoyama and matsumura 2008). (kirkels and verbonG 2011).

242

biological systems

these processes are suitable for very wet biomass materials such as food or agricultural wastes, including farm animal slurry. anaerobic digestion

anaerobic digestion means the breakdown of organic waste by bacteria in an oxygen-free environment. this produces a biogas typically made up of 65% methane and 35% carbon dioxide. purified biogas can then be used both for heating and electricity generation. fermentation

fermentation is the process by which growing plants with a high sugar and starch content are broken down with the help of micro-organisms to produce ethanol and methanol. the end product is a combustible fuel that can be used in vehicles. biomass power station capacities typically range up to 15 mW, but larger plants are possible. however bio mass power station should use the heat as well, in order to use the energy of the biomass as much as possible, and therefore the size should not be much larger than 25 mW (electric). this size could be supplied by local bioenergy and avoid unsustainable long-distance fuel supply.

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[r]evolution

biofuels

converting crops into ethanol and bio diesel made from rapeseed methyl ester (rme) currently takes place mainly in brazil, the usa and europe. also processes to produce synthetic fuels from ‘biogenic synthesis’ gases will play a larger role in the future, especially for aviation and marine transport systems. theoretically, biofuels can be produced from any biological carbon source, although the most common are photosynthetic plants. various plants and plantderived materials are used for biofuel production. Globally, biofuels are most commonly used to power vehicles but can also be used for other purposes. the production and use of biofuels must result in a net reduction in carbon emissions compared to the use of traditional fossil fuels to have a positive effect in climate change mitigation. sustainable biofuels can reduce the dependency on petroleum and thereby enhance energy security. • bioethanol is a fuel manufactured through the fermentation of sugars. sugars are used directly (sugar cane or beet) or by breaking down starch in grains such as wheat, rye, barley or maize. in the european union, bioethanol is mainly produced from grains, with wheat as the dominant feedstock. in brazil, the preferred feedstock is sugar cane, whereas in the usa it is corn (maize). bioethanol produced from cereals has a byproduct, a protein-rich animal feed called dried distillers Grains with soluble (ddGs). for every tonne of cereals used for ethanol production, on average one third will enter the

animal feed stream as ddGs. because of its high protein level, ddGs is currently used as a replacement for soy cake. bioethanol can either be blended into gasoline (petrol) directly or be used in the form of etbe (ethyl tertiary butyl ether). • biodiesel is a fuel produced from vegetable oil sourced from rapeseed, sunflower seeds or soybeans along with used cooking oils or animal fats. if used vegetable oils are recycled as feedstock for biodiesel production, pollution from discarded oil is reduced, providing a new way of transforming a waste product into transport energy. blends of biodiesel and conventional diesel are the most common products distributed in the retail transport fuel market. • most countries use a labelling system to explain the proportion of biodiesel in any fuel mix. fuel containing 20% biodiesel is labelled b20, while pure biodiesel is referred to as b100. blends of 20 % biodiesel with 80 % petroleum diesel (b20) can generally be used in unmodified diesel engines. used in its pure form, b100 may require certain engine modifications. biodiesel can also be used as a heating fuel in domestic and commercial boilers. older furnaces may contain rubber parts that would suffer from biodiesel’s solvent properties but can otherwise burn it without any conversion. there are many different biomass feedstock types and numerous conversion technologies to produce fuels for heat and/or power and transport technologies; figure 10.12 provides a simplified overview.

figure 10.12 | schematic view of commercial bioenergy routes 27 FEEDSTOCK1 OIL CROPS (RAPE, SUNFLOWER ETC), WASTE OILS, ANIMAL FATS

CONVERSION ROUTES2

HEAT AND/OR POWER LIQUID FUELS

(BIOMASS UPGRADING3) + COMBUSTION

BIODIESEL TRANSESTERIFICATION OR HYDROGENATION BIOETHANOL

SUGAR AND STARCH CROPS

(HYDROLOSIS) + FERMENTATION SYSDIESEL

LIGNOCELLULOSIC BIOMASS (WOOD, STRAW, ENERGY CROP, MSW, ETC.)

GASIFICATION

METHANOL, DME PYROLYSIS

BIODEGRADABLE MSW, SEWAGE SLUDGE, MANURE, WET WASHES (FARM AND FOOD WASTERS), MACRO-ALGAE

(+ SECONDARY PROCESS) OTHER FUELS AND FUEL ADDITIVES

AD4

(+ BIOGAS UPGRADING)

OTHER BIOLOGICAL PHOTOSYNTHETIC MICRO-ORGANISMS, E.G. MICROALGAE AND BACTERIA

/ RENEWABLE DIESEL

(+ SECONDARY PROCESS)

/ CHEMICAL ROUTES

TRANSESTERIFICATION OR HYDROGENATION

GASEOUS FUELS BIOMETHANE

HYDROGEN

1 parts of each feedstock, e.g. crop residues, could also be used in other routes. 2 each route also gives co-products. 3 biomass upgrading includes any one of the densification processses) pelletisation, pyrolysis, torrefaction, etc.) 4 ad = anaerobic digestion source iea-bio 2009

references 27

(iea bio-2009) bioenerGy – a sustainable and reliable enerGy source main report; international enerGy aGency 2009.

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world energy [r]evolution a sustainable world energy outlook

10.4.9 bioenergy and greenhouse gas (ghg) emission reduction

it is of great importance that bioenergy lower greenhouse gas emissions; only then does the use of bioenergy make ecologic sense. the ranges of GhG emissions per unit of energy output (mj) from major modern bioenergy chains compared to conventional and selected advanced fossil fuel energy systems (land use-related net changes in carbon stocks and land management impacts are excluded) are shown in figure 10.13. commercial and developing (such as algae biofuels, fischer-tropsch, etc.) systems for biomass and fossil technologies are illustrated.

greenpeace has a very strict policy in order to use only sustainable bioenergy in future energy systems. guidelines for the future use of bioenergy are documented in chapter 8.

figure 10.13 | ghg emissions of bioenergy and fossil fuels

600

10 Lifecycle GHG emissions (g CO2eq / Mj)

TRANSPORTATION

ELECTRICITY

HEAT

500 400

DIESEL SUBSTITUTES FROM BIOMASS, COAL AND COAL/BIOMASS

ETHANOL AND GASOLINE

BIOGAS AND NATURAL GAS

300

BIODIESEL (BD), RENEWABLE DIESEL (RD) AND FISCHER TROPSCH DIESEL (FTD)

200

BIOMASS AND COAL TO LIQUIDS (B/CTL)

CO2 SAVINGS

100 0

n n n

modern bioenerGy fossil fuel enerGy bctl

note ccs = carbon capture and storage source ipcc-srren 2012

244

FOSSIL ELECTRIC HEATING

NATURAL GAS

OIL

COAL

BIOMASS

FOSSIL GAS

OIL

COAL

BIOGAS

BIOMASS

NATURAL GAS

BIOGAS

PETROLEIUM DIESEL

CTL (FT DIESEL W/CCS)

CTL (FT DIESEL) (W/ OR W/O POWER)

(10% TO 55% BIOMASS W/ CCS) BCTL

(10% BIOMASS W/ OR W/O POWER) BCTL

LIGNOCELLULOSE FTD

PLANT OILS RD

ALGAE BD

PLANT OIL BD

PETROLEUM GASOLINE

LIGNOCELLULOSE

CORN AND WHEAT

SUGAR BEAT

SUGARCANE

-100

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[r]evolution

10.4.10 geothermal energy

Geothermal energy is heat derived from underneath the earth’s crust. in most areas, this heat comes from a long way down and has mostly dissipated by the time it reaches the surface, but in some places the geothermal resources are relatively close to the surface and can be used as nonpolluting sources of energy. these “hotspots” include the western part of the usa, west and central eastern europe, iceland, asia and new Zealand (the pacific rim). the uses of geothermal energy depend on temperatures. low and moderate areas temperature areas (less than 90°c or between 90°c and 150°c, respectively) can be used for their heat directly, while the highest temperature resources (above 150°c) are suitable only for electric power generation. today’s total global geothermal generation is approximately 10,700 mW, with nearly one-third in usa (over 3,000 mW), and the next biggest share in philippines (1,900 mW) and indonesia (1,200 mW) (ipcc-srren 2012). 28 technology and applications

Geothermal energy is currently extracted using wells or other means that produce hot fluids from either hydrothermal reservoirs with naturally high permeability or reservoirs engineered and fractured to extract heat. see below for more information on these “enhanced geothermal systems”. production wells discharge hot water and/or steam. in high-temperature hydrothermal reservoirs, water occurs naturally underground under pressure in liquid from. as it is extracted, the pressure drops, and the water is converted to steam to a turbine that generates electricity. any remaining hot water may go through the process again to obtain more steam. the remaining salty water is sent back to the reservoir through injection wells, sometimes via another system to use the remaining heat. a few reservoirs, such as the Geysers in the usa, larderello in italy, matsukawa in japan, and some indonesian fields, naturally produce steam vapour that can be used in a turbine. hot water produced from intermediatetemperature hydrothermal or enhanced Geothermal system (eGs) reservoirs can also be used in heat exchangers to generate power in a binary cycle, or in direct use applications. recovered fluids are also injected back into the reservoir. 29 the key technologies are: exploration and drilling includes estimating where the resource

is, its size and depth with geophysical methods and then drilling exploration wells to test the resource. today, geothermal wells are drilled over a range of depths down to 5 km using methods similar to those used for oil and gas. advances in exploration and drilling can technology can be expected. for example, if several wells are drilled from the same pad, it can access more heat resources and minimize the surface impact. 30

reservoir engineering is focused on determining the volume of

geothermal resource and the optimal plant size. the optimum has to consider sustainable use of the resources and safe, efficient operation. the modern method of estimating reserves and sizing power plants is ‘reservoir simulation’ – a process that starts with a conceptual model followed by a calibrated, numerical representation. 31 then, future behaviour is forecast under selected load conditions using an algorithm (such as touGh2) to select the plant size. injection management looks after the production zones, and uses data to make sure the hot reservoir rock is re-charged sufficiently. geothermal power plants use the steam created from heating

water via natural underground sources to power a turbine that produces electricity. the technique has been used for decades in the us, new Zealand and iceland and is under trial in Germany, where it is necessary to drill many kilometres down to reach high-temperature zones. the basic types of geothermal power plants in use today are steam-condensing turbines, binary-cycle units and cogeneration plants. • steam condensing turbines can be used in flash or drysteam plants operating at sites with intermediate and hightemperature resources (≥150°c). the power units usually have 20 to 110 mWe (dipippo, 2008) and may utilize a multiple-flash system, obtaining steam at successively lower pressures to get as much energy as possible from the geothermal fluid. the only difference between a flash plant and a dry-steam plant is that the latter does not require brine separation, resulting in a simpler and cheaper design. • binary-cycle plants, typically organic rankine cycle (orc) units, typically extract heat from low and intermediatetemperature geothermal fluids from hydrothermal and eGs reservoirs. binary plants are more complex than condensing ones since the geothermal fluid (water, steam or both) passes through a heat exchanger to heat another working fluid (such as isopentane or isobutene), which vaporises, drives a turbine, and then is air-cooled or condensed with water. binary plants are often constructed as smaller, linked modular units (a few mWe each). • combined or hybrid plants comprise two or more of the above basic types to improve versatility, increase overall thermal efficiency, improve load-following capability, and efficiently cover a wide resource-temperature range. • cogeneration plants or combined / cascaded heat and power plants (chp) produce both electricity and hot water for direct use. they can be used in relatively small industries and communities of a few thousand people. iceland, for example, runs geothermal cogeneration plants with a combined capacity of 580 mWth. 32 at the oregon institute of technology, a chp plant cover most of the electricity and all the heat demand. 33 references 28 29 30 31 32 33

(ipcc-srren 2012); chapter 4 Geothermal enerGy. armstead and tester, 1987; dickson and fanelli, 2003; dipippo, 2008. ipcc, srren 2012. Grant et al., 1982. hjartarson and einarsson, 2010. lund and boyd, 2009.

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10.4.11 enhanced geothermal systems (egs) figure 10.14 | scheme showing an enhanced geothermal system (egs) Heat Exchanger Cooling Unit Rechange Reservoir

ORC or Kalina Cycle

Reservoir Monitoring

Power

District Heating

Monitoring Well Inj Injection Well Wel

Monitoring Well

Production Produc duction duc Wells

3 km to 10 km

in some areas, the subsurface regions are â&#x20AC;&#x2DC;stimulatedâ&#x20AC;&#x2122; to make use of geothermal energy for power generation. a reservoir is made by creating or enhancing a network of fractures in the rock underground so fluid can move between the injection point and where power is produced (production wells) (see figure 10.14). heat is extracted by circulating water through the reservoir in a closed loop; it can be used for power generation or heating via the technologies described above. recently developed models provide insights into geothermal exploration and production. eGs projects are currently at a demonstration and experimental stage in a number of countries. the key challenges are creating enough reservoirs with sufficient volumes for commercial rates of energy production, while protecting water resources and avoiding instability of the earth or seismicity (earthquakes). 34

Enhanced Reservoir

-1

source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press.

figure 10.15 | schematic diagram of a geothermal condensing steam power plant (top) and a binary-cycle power plant (bottom) Cooling Tower

Condenser Turbo Generator Separator Steam

Steam Water

Production Well

Water Pump

Water

Injection Well

Cooling Tower

Heat Exchanger Turbo Generator

Heat Exchanger

Steam Water

Feed Pump

Water Pump

Production Well Injection Well

source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press.

references 34

246

tester et al., 2006.

energy

[r]evolution

10.4.12 hydropower

classification by facility type

Water has been used to produce electricity for about a century. even today, it covers around one fifth of the world’s power demand. the main requirement for hydropower is to create an artificial head of water that has sufficient energy to power a turbine when diverted into a channel or pipe.

hydropower plants are also classified in the following categories according to operation and type of flow: • run-of-river (ror) • storage (reservoir) • pumped storage, and

classification by head and size

the ‘head’ in hydropower refers to the difference between the upstream and the downstream water levels, which determines the water pressure on the turbines. along with discharge, the pressure level determines what type of hydraulic turbine is used. the classification of ‘high head’ and ‘low head’ varies from country to country, and there is no generally accepted scale. broadly, pelton impulse turbines are used for high heads (where a jet of water hits a turbine and reverses direction). francis reaction turbines are used to exploit medium heads (which run full of water and in effect generate hydrodynamic ‘lift’ to propel the turbine blades). for low heads, kaplan and bulb turbines are applied. classification according to refers to installed capacity measured in mW. small-scale hydropower plants are more likely to be runof-river facilities than are larger hydropower plants, but reservoir (storage) hydropower stations of all sizes use the same basic components and technologies. it typically takes less time and effort to construct and integrate small hydropower schemes into local environments35 so their deployment is increasing in many parts of the world. small schemes are often considered in remote areas where other energy sources are not viable or are not economically attractive.

• in-stream technology, technology.

young

and

less-developed

run - of - river

these plants draw the energy for electricity mainly from the available flow of the river and do not collect significant amounts of stored water. they may include some short-term storage (hourly, daily), but the generation profile will generally be dictated by local river flow conditions. because generation depends on rainfall, it may have substantial daily, monthly or seasonal variations, especially when located in small rivers or streams with widely varying flows. in a typical plant, a portion of the river water might be diverted to a channel or pipeline (penstock) to convey the water to a hydraulic turbine connected to an electricity generator (see figure 10.16). ror projects may form cascades along a river valley, often with a reservoir-type hydropower plants in the upper reaches of the valley. run-of-river installation is relatively inexpensive. facilities typically have lower environmental impacts than similar-sized storage hydropower plants.

figure 10.16 | run-of-river hydropower plant

greenpeace supports the sustainability criteria developed by the international rivers network (www.internationalrivers.org).

Desilting Tank

Diversion Weir Intake

Headrace Forebay

Penstock

Powerhouse

Tailrace

Stream

source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press. references 35

eGre and mileWski, 2002.

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storage hydropower

pumped storage

hydropower projects with a reservoir are also called storage hydropower. the reservoir reduces dependence on the variability of inflow, and the generating stations are located at the dam toe or further downstream, connected to the reservoir through tunnels or pipelines (figure 10.17). reservoirs are designed according to the landscape. in many parts of the world, river valleys are inundated to make an artificial lake. in geographies with mountain plateaus, highaltitude lakes are another kind of reservoir that retains many of the properties of the original lake. in these settings, the generating station is often connected to the reservoir lake via tunnels (lake tapping). for example, in scandinavia, natural high-altitude lakes create high pressure systems where the heads may reach over 1,000 m. a storage power plant may have tunnels coming from several reservoirs and may also be connected to neighbouring watersheds or rivers. large hydroelectric power plants with concrete dams and extensive collecting lakes often have very negative effects on the environment, requiring the flooding of habitable areas.

pumped storage plants generate electricity but are energy storage devices. in such a system, water is pumped from a lower reservoir into an upper reservoir (figure 10.18), usually during off-peak hours when electricity is cheap. the flow is reversed to generate electricity during the daily peak load period or at other times of need. the plant is a net energy consumer overall, because it uses power to pump water; however, the plant provides system benefits by helping to meet fluctuating demand profiles. pumped storage is the largest-capacity form of grid energy storage now readily available worldwide.

figure 10.17 | typical hydropower plant with reservoir

figure 10.18 | typical pumped storage power plant

Upper Reservoir

Pumping

Dam

Generating

Penstock Powerhouse

Pumped Storage Power Plant

Switch Yard Lower Reservoir

Tailrace

source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press.

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source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press.

energy

[r]evolution

in - stream technology using existing facilities

there are 3 classes of hydro power plants:

to optimize existing facilities like weirs, barrages, canals or falls, small turbines or hydrokinetic turbines can be installed for electricity generation. these basically function like a runof-river scheme, as shown in figure 10.19. hydrokinetic devices being developed to capture energy from tides and currents may also be deployed inland for free-flowing rivers and engineered waterways.

• large hydropower (>10 mWelectric);

hydropower – future developments

• small hydropower (≤10 mWelectric) • mini-hydro (100 kWe to 1 mWelectric) small-scale hydropower (from 1 mW to 10 mW) has a much wider range of designs, equipment, and material. therefore, expertise in a wider range of fields is crucial towards tapping the potential of local resources affordably and without a detrimental environmental impact (irena-hydro-2015).

a relatively small number of equipment suppliers dominate the market for large hydropower plants (above 10 megawatts). the basic equipment remains the same, though it has improved efficiency, with additional services ranging from monitoring and diagnostics to advanced control systems. more r&d is needed to produce further progress and reduce the considerable impact of large hydropower on environmental systems and local communities (irena-hydro2015). 36 the local population must be consulted before projects are further developed.

upgrades are an excellent way of getting more energy from existing hydropower facilities – and often the least-cost option. realistically, 5-10 percent more electricity can be generated at modest cost. legal and technical hurdles may, however, hamper repowering, for instance when there is limited documentation from decades ago. today, it is possible to accurately analyse local geology and hydrology in advance in order to assess potential gains from upgrades (irenahydro-2015). in energy [r]evolution scenarios, up-grading of existing hydropower plants is of particular importance and preferred to new builds, especially for large power plants.

figure 10.19 | typical in-stream hydropower plant

greenpeace does not support large hydropower stations that require large dams and flooding areas but does support small-scale run-of-river power plants.

Spillway

Diversion Canal 10.4.13 ocean energy wave energy

Irrigation Canal

Switch Yard

Powerhouse Tailrace Channel

source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press.

references 36

(irena-hydro 2015) hydropoWer – technoloGy brief; iea-etsap and irena technoloGy brief e06 – february 2015. WWW.etsap.orG – WWW.irena.orG; international reneWable enerGy aGency (irena); enerGy technoloGy systems analysis proGramme. (ipcc-srren 2012), chapter 6.

in wave power generation, a structure interacts with the incoming waves, converting this energy to electricity through a hydraulic, mechanical or pneumatic power take-off system. the structure is moored or placed directly on the seabed/seashore. power is transmitted to the seabed by a flexible submerged electrical cable and to shore by a sub-sea cable. Wave power can potentially provide a predictable supply of energy and does not create much visual impact. many wave energy technologies are at an early phase of conceptual development and testing. power plants designs vary to deal with different wave motion (heaving, surging, pitching) water depths (deep, intermediate, shallow) and distance from shore (shoreline, near-shore, offshore). shoreline devices are fixed to the coast or embedded in the shoreline. near-shore devices work at depths of 20-25 m to ~500 m from the shore, where there are stronger, more productive waves. offshore devices exploit the more powerful waves in water over 25 m deep (ipcc-srren 2012). 37 no particular technology is dominant for wave power. several different systems are being prototyped and tested at sea, with most development being carried out in uk.

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a generic scheme for characterizing ocean wave energy generation devices consists of primary, secondary and tertiary conversion stages, 38 which refer to the conversions of kinetic energy (in water) to mechanical energy, and then to electrical energy in the generator. recent reviews have identified more than 50 wave energy devices at various stages of development, 39 and we have not explored the limits of size in practice. utility-scale electricity generation from wave energy will require arrays of devices, and like wind turbines, devices are likely to be chosen for specific site conditions. Wave power converters can be made up from connected groups of smaller generator units of 100 – 500 kW, or several mechanical or hydraulically interconnected modules can supply a single larger turbine generator unit of 2 – 20 mW. however, large waves needed to make the technology more cost effective are mostly a long way from shore which would require costly sub-sea cables to transmit the power. the converters themselves also take up large amounts of space.

Wave energy systems may be categorised by their genus, location and principle of operation as shown in figure 10.20. oscillating water columns

oscillating water columns use wave motion to induce different pressure levels between the air-filled chamber and the

atmosphere.40 air is pushed at high speed through an air turbine coupled to an electrical generator (figure 10.21), creating a pulse when the wave advances and recedes, as the air flows in two directions. the air turbine rotates in the same direction, regardless of the flow. a device can be: a fixed structure above the breaking waves (cliff-mounted or part of a breakwater); bottom-mounted near shore; or it can be a floating system moored in deeper waters. oscillating - body systems

oscillating-body systems use the incident wave motion to make two bodies move in oscillation to drive the power take-off system.41 they can be surface devices or, less often, fully submerged. surface flotation devices are generally referred to as ‘point absorbers’, because they are non-directional. some oscillating body devices are fully submerged and rely on oscillating hydrodynamic pressure to extract the wave energy. lastly, hinged devices sit on the seabed relatively close to shore and harness the horizontal surge energy of incoming waves. overtopping devices

overtopping devices convert wave energy into potential energy by collecting surging waves into a water reservoir at a level above the free water surface. 42 the reservoir drains down through a conventional low-head hydraulic turbine. these systems can float offshore or be incorporated into shorelines or man-made breakwaters (figure 10.23).

figure 10.20 | wave energy: classification based on principles of operation

shore-baseD

oscillating water colUmn floating heaving bUoys sUrface bUoyant rotational Joints

oscillating boDy pressUre heaving sUbmergeD sUrge, hingeD rotation

shore-baseD

overtopping

concentrating breakwater floating

source falcao 2009.

references 38 39 40 41 42

(khan et al., 2009). falcao, 2009; khan and bhuyan, 2009; us doe, 2010. falcao et al., 2000; falcao, 2009. falcao, 2009. falcao, 2009.

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non-concentrating breakwater

energy

[r]evolution

power take - off systems

power take-off systems are used to convert the kinetic energy, air flow or water flow generated by the wave energy device into a useful form, usually electricity. a large number of different technology options are described in the literature. 43 the overall concept is that real-time wave

oscillations will produce corresponding electrical power oscillations. in practice, some method of short-term energy storage (in seconds) may be needed to smooth energy delivery. these devices would probably be deployed in arrays because the cumulative power generated by several devices will be smoother than from a single device.

figure 10.21 | oscillating water columns

Air Flow Air Flow In-Take In-Take Electric Electric Generator Generator

Rotor Rotor

Wave Wave Crest Crest

Wave Wave Trough Trough

Rising Rising Water Water Column Column

Falling FallingWater Water Column Column

source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press.

figure 10.22 | oscillating-body systems

figure 10.23 | overtopping devices

Stationary Center Spar

Float

Reservoir

Overtopping

Upward Motion

Turbine Downward Motion Cable Mooring

Turbine Outlet

source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press.

references 43

khan and bhuyan, 2009.

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world energy [r]evolution a sustainable world energy outlook

tidal range

tidal and ocean currents

tidal range hydropower has been tested in estuarine developments where a barrage encloses an estuary, which creates a single reservoir (basin) behind it with conventional low-head hydro turbines in the barrage. alternative configurations of multiple barrages have been proposed where basins are filled and emptied at different times, with turbines located between the basins. multi-basin schemes may offer more flexible power generation availability than normal schemes because they could generate power almost continuously.

to capture energy from tidal currents, a device can be fitted underwater to a column fixed to the sea bed with a rotor to generate electricity from fast-moving currents, technologies that extract kinetic energy from tidal and ocean currents are under development; tidal energy converters are the most common to date, designed to generate as the tide travels in both directions. devices types include axial-flow turbines, cross-flow turbines and reciprocating devices. axial-flow turbines (figure 10.26 see below) work on a horizontal axis, while cross-flow turbines may operate about a vertical axis (figure 10.27 see below) or a horizontal axis with or without a shroud to accentuate the flow. a single unit can have multiple turbines (figure 10.27).

recent developments focus on single or multiple offshore basins away from estuaries (â&#x20AC;&#x2DC;tidal lagoonsâ&#x20AC;&#x2122;), which could provide more flexible capacity and output with little or no impact on delicate estuarine environments. this technology uses commercially available systems. the conversion mechanism most widely used to produce electricity from tidal range is the bulb-turbine. 44 examples of power plants with bulb turbines technology include a 240 mW power plant at la rance in northern france 45 and the 254 mW sihwa barrage in the republic of korea, which is nearing completion. 46 some favourable sites with very gradually sloping coastlines are well suited to tidal range power plants, such as the severn estuary between southwest england and south Wales. current feasibility studies there include options such as barrages and tidal lagoons. the average capacity factor for tidal power stations has been estimated from 22.5% to 35%. 47

marine turbine designs look somewhat like wind turbines but must contend with reversing flows, cavitation and harsh underwater marine conditions (salt water corrosion, debris, fouling, etc.). axial flow turbines must be able to respond to reversing flow directions, while cross-flow turbines continue to operate regardless of current flow direction. rotor shrouds (also known as cowlings or ducts) can enhance hydrodynamic performance by increasing the speed of water through the rotor and reducing losses at the tips. some technologies in the conceptual stage of development are based on reciprocating devices incorporating hydrofoils or tidal sails. two prototype oscillating devices have been trialled at open sea locations in the uk. 48 the development of tidal current resources will require multiple machines deployed in a similar fashion to a wind farm, and siting will need to take into account wake effects. 49

figure 10.24 | classification of current tidal and ocean energy technologies (principles of operation)

axial flow tUrbines

shroUDeD rotor

open rotor

source ipcc-srren 2012.

references 44 45 46 47 48 49

bosc, 1997. andre, 1976; de laleu, 2009. paik, 2008. charlier, 2003; etsap 2010b. enGineerinG business, 2003; tsb, 2010. peyrard et al. 2006.

252

cross flow tUrbines

shroUDeD rotor

open rotor

reciprocating Devices

vortex inDUceD

magnUs effect

flow flUtter

energy

[r]evolution

capturing the energy of open-ocean current systems is likely to require the same basic technology as for tidal flows but with some different infrastructure. deep-water applications may require neutrally buoyant turbine/generator modules with mooring lines and anchor systems. they could also be attached to other structures, such as offshore platforms. 50 these modules will also have hydrodynamic lifting designs to allow for optimal and flexible vertical positioning.51 systems to capture energy from open ocean current systems may have larger rotors, as there is no restriction based on the channel size.

ocean energy â&#x20AC;&#x201C; future developments

figure 10.25 | twin turbine horizontal axis device

figure 10.27 | cross flow device

ocean energy can play a significant role for the power supply of islands and coastal regions. a combination with offshore wind farms, ocean energy power plants might help to integrate larger shares of flexible one-shore and/or solar photovoltaic electricity. Greenpeace supports the developments of ocean energy in a sustainable manner.

Generator

Tidal Stream

Rotation

source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press.

figure 10.26 | vertical axis device

source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press.

references 50 51

vanZWieten et al., 2005. veneZia and holt, 1995; raye, 2001; vanZWieten et al., 2005.

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10.5 power grid technologies – infrastructure for renewables With increasing market shares of renewable power generation, there will be less space for base load power plants. as a result conventional power plants cannot run in base load mode anymore, which increases costs of operation and therefore lowers the profit on each kWh sold. the integration of large-scale renewable energy requires a variety of existing grid technologies applied in a new context and with new operational concepts. this section provides a short overview of technologies and operational concepts used for the integration of large shares of renewables and are based on Greenpeace international’s reports about power grids published between 2009 and 2014 (Gpi- en 2014). 52

smart-grid technology will play a significant role, in particular by integrating demand-side management into power system operation. the future power supply will not consist of a few centralized power plants, but of numerous smaller generation units, such as solar panels, wind turbines and other renewable units, partly on the distribution network and partly concentrated in large power plants (such as offshore wind farms). smart-grid solutions will help to monitor and integrate this diversity into power system operation and at the same time will make interconnection simpler. the tradeoff is that power system planning will become more complex due to the larger number of generation assets and the significant share of variable power generation causing constantly changing power flows in the power systems. smart-grid technology will be needed to support power system planning, i.e. actively support day-ahead planning and power system balancing by providing real-time information about the status of the network and the generation units in combination with weather forecasts. smart-Grid technology will also play a significant role in making sure systems can meet the peak demand at all times. smart-Grid technology will make better use of distribution and transmission assets, thereby limiting the need for transmission network extension to the absolute minimum. smart grids use information and communication technology (ict) to enable a power system based on renewable energy sources. ict in smart grids is used to: • easily interconnect a large number of renewable generation assets into the power system (plug and play) • create a more flexible power system through large-scale demand-side management and by integrating storage to balance the impact of variable renewable generation resources • provide the system operator with a better information about the state of the system, which so they can operate the system more efficiently references 52

(Gpi-en 2014) poWe[r] 2030 -. a european Grid for 3/4 reneWable electricity by 2030; Greenpeace international / enerGynautics; march 2014.

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• minimize network upgrades using of network assets efficiently and supporting an efficient coordination of power generation over very large geographic areas needed for renewable energy generation. 10.5.1 demand side management

in reality, load varies over time which means that additional flexible power generation resources are required to provide the right amount of power. for rural areas, typical technologies are combined-cycle gas turbines (ccGt) or hydro-power stations with a sufficient storage capacity to follow the daily load variations. in conventional island power systems, typically a number of small diesel generators (gensets) are used to provide 24/7 supply. several gen-sets have to operate continuously at the point of their highest efficiency, while one is used to follow the load variations. the impact of adding renewable power generation to a conventionally centralized or island power system will affect the way in which a conventionally designed electricity system runs. the level of impact depends on the renewable energy technology: biomass, geothermal-, concentrated solar- and hydropower with storage can regulate power output and therefore can supply base load as well as peak load. hydropower without storage (run–of- river), photovoltaic and wind power depends on the available natural resources, so the power output is variable. sometimes these renewable energy sources are sometimes described as ‘intermittent’ power sources; however, the terminology is not correct as intermittent stands for uncontrollable, i.e. non-dispatchable, but the power output of these generation plants can be forecast, so they can be dispatched. furthermore, they can always be ramped down if needed.there are two main types of impacts to consider when introducing renewable energy to micro-grids: the balancing impact and reliability impact. balancing impact to relates to the short-term adjustments

needed to manage fluctuations over a period ranging from minutes to hours before the time of delivery. in power systems without variable power generation, there can be a mismatch between demand and supply. the reasons could be that the energy load was not forecast correctly, or a conventional power plant is not operating as it is scheduled, for instance when a power station trips due to a technical problem. adding a variable power generation source increases the risk that the forecast power generation in the power system will not be reached, for instance due to a weather system moving faster than predicted into the area. the overall impact on the system depends on how large and how widely distributed the variable power sources are. a certain amount of wind power distributed over a larger geographical area will have a lower

energy

[r]evolution

impact on system balancing than the same amount of wind power concentrated in one single location, as geographical distribution will smoothen out the renewable power generation. system balancing is relevant to: • Day-ahead planning, which needs to make sure that sufficient generation is available to match expected demand taking into account forecasted generation from variable power generation sources (typically 12 to 36 hours ahead); • short-term system balancing, which allocates balancing resources to cover events such as a mismatch between forecasted generation/demand or sudden loss of generation (typically seconds to hours ahead planning). in island power systems, both aspects must be handled automatically by the system. reliability impact is the extent to which sufficient generation

will be available to meet peak demands at all times. no electricity system can be 100% reliable, since there will always be a small chance of major failures in power stations or transmission lines when demand is high. as renewable power production is often more distributed than conventional large-scale power plants, it reduces the risk of sudden dropouts of major individual production units. on the other hand, variable renewable power generation reduces the probability that generation is available at the time of high demand, thus adding complexity to system planning. reliability is important for long-term system planning, which assesses the system adequacy typically two to 10 years ahead. long-term system planning with variable generation sources is a challenge, because of the actual geographical location of the resource. to get a high level of renewable energy into the system, it ideally must be situated at some distance from each other, for example using solar power from southern europe when there is no or limited wind power available in northern europe. in island power systems, all power generation is typically close to each other, which means that there must be a mix of different generation technologies in the island system or that they must be partly over-designed to make sure that there is always sufficient generation capacity available. this is typically done by adding some back-up diesel gen-sets. in addition, island power systems can adjust power demand to meet power supply, rather than the other way round. this approach is called demand-side management. an example of a “flexible” load in island systems for demand-side management is water pumps and irrigation pumps, which can be turned on and off depending on how much electricity supply there is.

10.5.2 “overlay” or “super grid” – the interconnection of smart grids

based on the current technology development of energy storage technologies, it is difficult to envision that energy storage could provide a comprehensive solution to this challenge. While different storage technologies such as electrochemical batteries are already available today, it is not clear whether large-scale electricity storage, other than pumped hydropower described in the previous section, will become technically and economically viable. feasible storage systems would have to cover most of the european electricity supply during up to two successive weeks of low solar radiation and little wind – difficult to envision based on current technology development. to design a power system that can adequately react to such extreme situations, a substantial amount of planning is needed in order to ensure available generation capacity together with sufficient network capacity to match demand. different timescales must be considered: • long-term system plans to assess the system adequacy over the coming years (typically a time horizon of 2 to 10 years ahead) • day-ahead planning, making sure that sufficient generation is available to match expected demand (typically 12 to 36 hours ahead) • short-term balancing, covering events such as a mismatch between forecasted generation/demand or sudden loss of generation (typically seconds to hours-ahead planning) benefits of a super grid

starting around 1920, each load center in europe had its own isolated power system. With the development of transmission lines using higher voltages, the transport of power over larger distances became feasible. soon, the different centers were interconnected. in the beginning, only stations in the same region were interconnected. over the years, technology developed further, and maximum possible transmission line voltage increased step by step. there were two main drivers of extending network structure: • larger transmission networks and high voltage lines meant suppliers could follow the aggregated demand of a large number of customers, instead of the demand variation of one customer - which can change significantly over time with one generation resource. the demand of those aggregated customers became easier to predict and generation scheduling therefore significantly easier. • the larger transmission networks created economies of scale by installing larger generation units. in the 1930s, the most cost-effective size of thermal power stations was about 60 mW. in the 1950s, it was 180 mW, and by the 1980s about 1,000 mW. this approach made only

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economic sense because extending the power system was cheaper than adding local generation capacity. the approach includes some major risks, like the failure of a large power station or the interruption of a major transmission line, which can interrupt of the power system over a large area. to be better prepared for such situations national transmission systems in europe and elsewhere were interconnected across borders. countries can help each other in case of emergency situations by cooperating in the organization of spinning reserve, reserve capacity and frequency control. shifting to an energy mix with over 90% of the electricity supply coming from renewable energy sources will also require a significant redesign of the transmission network to adapt to the needs of the new generation structure. the right kind of grid provides an economic, reliable and sustainable energy supply.

in principal, over-sizing local generation locally would reduce the need for large-scale renewable generation elsewhere as well as upgrading the transmission network. in this case the local power system will evolve into a hybrid system that can operate without any outside support. however, making local plants bigger (over-sized) is less economical than installing large-scale renewable energy plants at a regional scale and integrating them into the power system via extended transmission lines. the allocation of 70% distributed renewable generation and 30% large-scale renewable generation is not based on a detailed technical or economic optimization; in each location, the optimum mix is specific to local conditions. further detailed studies on regional levels will be needed to better quantify the split between distributed and large-scale renewable generation better. an appropriately designed transmission system is the solution in both cases as it can be used to transmit the required electricity from areas with surplus of generation to areas that have an electricity deficit. in general, the transmission system must be designed to cope with: • long-term issues: extreme variations in the availability of natural resources from one year to another; for instance, the output of wind turbines in any given area can vary by up to 30% from one year to the next. for hydropower, the variations can be even larger • medium-term issues: extreme combinations in the availability of natural resources, such as no wind over main parts of europe during the winter, when solar radiation is low

references 53

hvac cable systems are currently less attractive as cable losses are hiGher and transmission capacity is less than With hvac overhead lines.

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• short-term issues: significant mismatch between forecasted wind or solar production and actual production with significant impact on power system operation in the range of 15 minutes to 3 hours • loss of a significant amount of generation due to unscheduled break-down or network interruption, impact within milliseconds. the mainland european power system is currently designed to cope with a maximum sudden generation loss of 3,000 mW. Whether this level is sufficient for the future depends, for example, on the maximum transmission capacity of a single transmission line. most likely the maximum transmission capacity of a single transmission in the future hvdc super Grid will exceed a capacity of 3,000 mW; hence, sufficient spare generation and/or network capacity must be considered when redesigning the power system (considered in the simulation report by loading the super Grid to a maximum of 70%). super grid transmission options

in principal different technical options exists for the redesign of the onshore transmission network. in the following, the following technical options are briefly presented, followed by a general comparison. • hvac (high voltage alternating current) • hvdc lcc (high voltage direct current system using line commutated converter) • hvdc vsc (high voltage direct current system using voltage source converter) • other technical solutions 10.5.3 hvac

high voltage ac transmission (hvac) using overhead lines has become a leading technology in electrical networks. 53 its advantage is in using transformers to increase the typical, rather low voltage from the generators to higher voltage levels, which is a significantly cheaper approach than the ac/dc converter stations for the hvdc technologies. transmission over long distances with low or medium voltage will result in high and prohibitively expensive losses, so high voltage ac (400 kv or more) over medium distance (a few hundred kilometers) is typically the most cost effective solution. as ac systems develop, there are increases in transmission voltage. typically, doubling the voltage quadruples the power transfer capability. consequently, the evolution of grids in most countries is characterized by the addition of network layers of higher and higher voltages. today, the highest hvac voltage used is around 800 kv for overhead lines. the canadian company hydro Quebec, for instance, operates a massive 735 kv transmission system using overhead lines; the first line was in operation 1965. 1000 kv and 1200 kv ac has been tested in several test-

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installations and even short-term commercial applications. there are several challenges involved in building such lines and new equipment needing to be developed includes transformers, breakers, transformers, and switches. the major advantage of an ac-based system is the flexibility with which loads and generation along the route can be connected. this is especially important if the transmission route passes through a highly populated area and if many local generation facilities are located at many places along the route. the disadvantage of hvac systems are the comparatively high costs for transmission of large capacity (> 1,000 mW) over very long distances (> 1000 km) due to the additional equipment required for keeping the voltage level on the overhead lines, for instance. 10.5.4 hvdc lcc

the advantage of line commutated converter (lcc) high voltage dc (hvdc) connections is certainly their proven track record. the first commercial lcc hvdc link was installed in 1954 between the island of Gotland and the swedish mainland. the link was 96 km long, rated at 20 mW, and used a 100 kv submarine cable. since then, lcc based hvdc technology has been installed in many locations in the world, primarily for bulk power transmission over long geographical distances and for interconnecting power systems, such as island systems in japan and new Zealand. other well-known examples for conventional hvdc technology are: • the 1,354 km pacific interie dc link with a rating of 3,100 mW at a dc voltage of ± 500 kv • the itaipu link between brazil and paraguay, rated at 6,300 mW at a dc voltage of ± 600 kv (2 bipoles x 3,150 mW) the total conversion efficiency from ac to dc and back to ac using the two converters lies in the range of 97 to 98 % and depends on the design details of the converter stations. a system design with a 98 % efficiency will have higher investment costs compared to a design with lower efficiency. the advantage of an lcc hvdc solution are comparatively low losses – in the order of 2-3 % for a 500 mW transmission over 100 km, including losses in converters and transmission. in addition, the higher transmission capacity of a single cable compared to hvac transmission and voltage source converter transmission can be an advantage when transmitting large capacities. the disadvantage of the hvdc lcc design is lack of power system support capability. typically, a strong hvac network is required on both sites of the hvdc lcc connection. hence, building up an entire hvdc back-bone network using hvdc lcc technology that has to support the underlying hvac network is technically challenging and only possible with the installation of additional equipment such as statcoms (= static synchronous compensator).

10.5.5 hvdc vsc

the voltage source converter (vsc) based hvdc technology is capturing more and more attention. this comparatively new technology has only become possible due to advances in high power electronics, namely insulated Gate bipolar transistors (iGbts). pulse Width modulation (pWm) can then be used for the vsc converter, as opposed to the thyristor line-commutated converters used in conventional hvdc technology. the first commercial vsc-based hvdc link was installed by abb on the swedish island of Gotland in 1999. it is 70 km long, with 60 mva at ± 80 kv. the link was mainly built in order to provide voltage support for the large amount of wind power installed in the south of Gotland. today about 10 vsc-based hvdc links are in operation world-wide. key projects are: • in 2000, the murraylink was built in australia with a length of almost 180 km. this connection was the longest vscbased hvdc link in the world until 2009. it has a capacity of 220 mva at a dc voltage of ±150 kv • the bard offshore 1 project borWind in Germany connects a 400 mW offshore wind farm to the onshore grid using a 203 km long cable, operating at a dc voltage of ±150 kv • the longest hvdc vsc project is the caprivi link in namibia. it is 970 km long and operates at ±350 kv, the highest voltage level used so far for hvdc vsc projects, to transmit a capacity of 300 mW. the total efficiency of a vsc-based hvdc system is slightly less than that of a lcc hvdc system, but efficiency is expected to improve with future technical development. also, rating per converter is presently limited to approximately 400500 mW, while the cable rating at +/-150 kv is 600 mW. more cable and converter stations are required for a vsc-based hvdc solution compared to an lcc-based hvdc solution; however, manufacturers are already working on converter stations with higher ratings and increased cable ratings. the significant advantages of vsc-based hvdc solutions are its power system support capabilities, such as independent control of active and reactive power. in addition, a vscbased hvdc link does not require a strong ac network, it can even start up against a non-load network. building up a vscbased hvdc backbone network will be technically easier than using lcc-based hvdc technology. however, multiterminal vsc hvdc systems are also new for the power system industry, so there will a learning curve to achieve it.

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comparison of transmission solutions

the cost of transmitting electricity is dominated by the investment cost of the transmission lines and by the electricity losses during transmission. at present, overhead lines are predominant since costs of overhead lines are about 20 % of that for ground cables. the transmission losses of hvac overhead lines are roughly twice as high as those of hvdc. on the one hand, the cost of overhead lines is similar for the lower voltage level, but at 800 kv hvdc lines are much less expensive than comparable ac lines. on the other hand, ac/dc converter stations for hvdc technology are considerably more expensive than the transformer stations of ac systems. therefore, for shorter distances and lower voltages ac is typically the most economical solution, while hvdc lines are applied at distances well over 500 km.

figure 10.28 | comparison of ac and dc investment costs using overhead lines total ac cost

total Dc cost break even distance 500-1,000 km investment cost

table 10.2 compares the three standard transmission solutions. the technical capabilities of each system can probably be improved by adding additional equipment to the overall system solution.

Dc line cost

Dc terminal cost ac line cost

ac terminal cost Distance source energynautics; dr thomas ackermann 2014. note the beak even point is typically between 500 to 1000 km.

table 10.2 | overview of the three main transmission solutions

maximum available capacity per system

hvac

lcc hvdc

vsc hvdc

cable system: • 200 mW at 150 kv; • 350 mW at 245 kv;

cable system: • ~ 1200 mW

cable/overhead: • 400 mW • 500 - 800 mW announced

overhead lines: • 2,000 mW at 800 kv • 4,000 mW at 1000 kv (under development) voltaGe level

cable system: • up to 245 kv realistic, short cables up to 400 kv possible overhead lines: • up to 800 kv • 1,000 kv under development

overhead lines: • 3,150 mW at ± 600 kv • 6,400 mW at ± 800 kv (under development) cable system: • up to ± 500 kv overhead lines: • up to ± 600 kv • ± 800 kv under development

cable: • up to ± 150 kv, higher voltages announced overhead lines: • up to ± 350 kv

transmission capacity distance dependinG?

yes

total system losses

distance depending

2 - 3 % (plus requirements for ancillary services offshore)

5 – 10 %

black start capability

(yes)

yes

technical capability for netWork support

limited

large range of possibilities.

space reQuirements for substation.

small

depending on capacity. converter depending on capacity. converter larger than vsc. smaller than lcc but larger than hvac substation.

source energynautics/Greenpeace/teske 2014 - powe[r] 2030.

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10.6 renewable heating and cooling technologies

the most economical system design is typically a combination of hvac and hvdc technology. hvac is a costeffective and flexible solution over medium distances (up to 1,000 km), for instance to distribute power along the route to different load centers or to collect locally distributed generation and transmit the surplus electricity to other regions. hvdc technology can be used as an overlaying network structure to transmit bulk power, i.e. large capacity, over long distances to the areas where the energy is needed. an hvdc super Grid will have only a very limited number of connection points, because the substation (converter station) costs are significant.

renewable heating and cooling has a long tradition in human culture. heat can come from the sun (solar thermal), the earth (geothermal), ambient heat and plant matter (biomass). solar heat for drying processes and wood stoves for cooking have been used for so long that they are labeled â&#x20AC;&#x153;traditionalâ&#x20AC;?, but todayâ&#x20AC;&#x2122;s technologies are far from old-fashioned. over the last decade, there have been improvements to a range of traditional applications, many of which are already economically competitive with fossil-fuel based technologies or starting to be.

in addition, an hvac solution will require significantly more lines than hvdc solutions. the transmission of 10,000 mW or 10 GW, for instance, can be achieved with two lines using 800 kv and applying lcc hvdc technology, while transmitting the same power with 800 kv ac would require five lines. for a given transmission capacity of 10 GW, the space requirement of hvdc overhead lines can be four times lower than that of hvac lines (figure 10.29). While an 800 kv hvac line would require a width of 425 meters over the total length of a power link of 10 GW, a hvdc line of the same capacity would only require a width of 100 meters. there are thus considerable differences in the environmental impact of both technologies.

this chapter presents the current range of renewable heating and cooling technologies and gives a short outlook of the most sophisticated technologies, integrating multiple suppliers and users in heat networks or even across various renewable energy sources in heating and cooling systems. some of the emerging areas for this technology are space heating / cooling and industrial process heat. 10.6.1 solar thermal technologies

solar thermal energy has been used for the production of heat for centuries but has become more popular and developed commercially for the last thirty years. solar thermal collecting systems are based on a centuries-old principle: the sun heats up water contained in a dark vessel.

figure 10.29 | comparison of the required number of parallel pylons and space to transfer 10 gw of electric capacity

Distribution Company

a final advantage of using hvdc technology is that it is easier to move the entire hvdc super grid underground by using hvdc cables. this approach will be more costly, but following existing transporting routes (laying the cables along motorways, railway tracks or even in rivers) will allow a fast roll-out of the hvdc supergrid infrastructure and reduce the visual impact of the installation.

Distribution Company

425 m

Distribution Company

800 kV AC

Distribution Company

150 m

Distribution Company

600 kV HVDC

800 kV HVDC

100 m source energynautics; dr thomas ackermann 2014.

the technologies on the market now are efficient and highly reliable, providing energy for a wide range of applications in domestic and commercial buildings, swimming pools, for industrial process heat, in cooling and the desalination for drinking water. although mature products exist to provide domestic hot water and space heating using solar energy, in most countries they are not yet the norm. a big step towards an energy [r]evolution is integrating solar thermal technologies into buildings at the design stage or when the heating (and cooling) system is being replaced, lowering the installation cost. swimming pool heating

pools can make simple use of free heating, using unglazed water collectors. they are mostly made of plastic, have no insulation and reach temperatures just a few degrees above ambient temperature. collectors used for heating swimming pools and are either installed on the ground or on a nearby rooftop; and they pump swimming pool water through the collector directly. the size of such a system depends on the size of the pool as well as the seasons in which the pool is used. the collector area needed is about 50 % to 70 % of the pool surface. the average size of an unglazed water collector system installed in europe is about 200 m 2. 54

references 54

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domestic hot water systems

the major application of solar thermal heating so far is for domestic hot water systems. depending on the conditions and the system’s configuration, most of a building’s hot water requirements can be provided by solar energy. larger systems can additionally cover a substantial part of the energy needed for space heating. two major collector types are:

tubes with copper fins attached. the entire structure is coated in a black substance designed to capture the sun’s rays. in general, flat plate collectors are not evacuated. they can reach temperatures of about 30°c to 80°c 55 and are the most common collector type in europe. there are two different way how the water flow is handle in solar heating, which influences the overall system cost.

vacuum tubes

thermo - siphon systems

the absorber inside the vacuum tube absorbs radiation from the sun and heats up the fluid inside. additional radiation is picked up from the reflector behind the tubes. Whatever the angle of the sun, the round shape of the vacuum tube allows it to reach the absorber. even on a cloudy day, when the light is coming from many angles at once, the vacuum tube collector can still be effective. most of the world’s installed systems are this type, especially in the world’s largest market: china. this collector type consists of a row of evacuated glass tubes with the absorber placed inside. due to the evacuated environment, there are less heat losses. the systems can reach operating temperatures of at least 120 °c; however, the typical use of this collector type is in the range of 60°c to 80°c. evacuated tube collectors are more efficient than standard flat-plate collectors but generally also more costly.

the simple form of a thermo-siphon solar thermal system uses gravity as a natural way to transfer hot water from the collector to the storage tank. no pump or control station is needed, and many are applied as direct systems without a heat exchanger, which reduces system costs. the thermo-siphon is relatively compact, making installation and maintenance quite easy. the storage tank of a thermo-siphon system is usually applied right above the collector on the rooftop and directly exposed to the seasons. these systems are typical in warm climates, due to their lower efficiency compared with forced circulation systems. the most common problems are heat losses and the risk of freezing; they are therefore not suitable for areas where temperatures drop below freezing. in southern europe, a system like this is capable of providing almost the total hot water demand of a household. however, the largest market for thermo-siphon systems is china. in europe, thermo-siphon solar hot water systems are 95% of private installations in Greece 56, followed by 25% and 15% of newly installed systems in italy and spain newly in 2009. 57

flat plate or flat panel

this is basically a box with a glass cover which sits on the roof like a skylight. inside is a series of copper or aluminium

figure 10.30 | natural flow systems vs. forced circulation systems

NATURAL FLOW SYSTEM (domestic hot water)

FORCED CIRCULATION SYSTEM (hot water & space heating)

source epia. 56

references 55

Weiss, W., et al. (2008): process heat collectors – state of the art. iea heatinG and coolinG proGramme and iea solarpaces proGramme, 2008. international enerGy aGency (iea), paris, france.

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travasaros, c. (2011): the Greek solar thermal market and industrial applications - overvieW of the market situation. Greek solar industry association, World sustainable enerGy days 2011, Wels, 3.3.2011, http://WWW.Wsed.at/fileadmin/redakteure/Wsed/2011/doWnload_presentations/travasaros.pdf. Weiss, W. et al. (2011): solar heat WorldWide - markets and contribution to the enerGy supply 2009. iea solar heatinG and coolinG proGramme, may 2011. international enerGy aGency (iea), paris, france.

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pumped systems

the majority of systems installed in europe are forced circulation (pumped) systems, which are far more complex and expensive than thermosiphon systems. typically, the storage tank is situated inside the house (for instance in the cellar). an automatic control pump circulates the water between the storage tank and the collector. forced circulation systems are normally installed with a heat exchanger, which means they have two circuits. they are mostly used in areas with low outside temperatures, and antifreeze additives might have to be added to the solar circuit to protect the water from freezing and destroying the collector. even though forced circulation systems are more efficient than thermosiphon systems, they are mostly not capable of supplying the full hot water demand in cold areas and are usually combined with a back-up system, such as heat pumps, pellet heaters or conventional gas or oil boilers. the solar coverage of a system is the share of energy provided by the solar system in relation to total heat consumption, such as space heating or hot water. solar coverage levels depend on the heat demand, the outside temperature and the system design. for hot water production, a solar coverage of 60% in central europe is common at the current state of technology development. the typical collector area installed for a domestic hot water system in a single family house in the eu 27 is 3-6 m 2. for multifamily houses and hotels, the size of installations is much bigger, with a typical size of 50 m 2. 58,59,60 domestic heat systems

besides domestic hot water systems, solar thermal energy for space heating systems is becoming increasingly relevant in european countries. in fact, the eu 28 is the largest market for this application at the moment, with Germany and austria as the main driving forces. the collectors used for these applications are, however, the same as for domestic hot water systems for solar space heating purposes, though only pumped systems are suitable. effectively most systems used are so called combisystems that provide space as well as water heating. so far, most installations are built on single-family houses with a typical system size between 6 and 16 m 2 and a typical annual solar coverage of 25 % in central europe. 58,59,60 solar combi-systems for multiple family houses are not yet used very frequently. these systems are about 50 m 2, cost approximately 470-550 €/m2 and have annual solar coverage of 25% in central europe. 58,59,60 large scale solar thermal applications connected to a local or district heating grids with a

references 58 59

60 61

Weiss, W. et al. (2011): solar heat WorldWide - markets and contribution to the enerGy supply 2009. iea solar heatinG and coolinG proGramme, may 2011. international enerGy aGency (iea), paris, france. nitsch, j. et al. (2010): leitstudie 2010 - lanGfristsZenarien und strateGien für den ausbau der erneuerbaren enerGien in deutschland bei berücksichtiGunG der entWicklunG in europa und Global. stuttGart, kassel, teltoW, deutsches Zentrum für luft- und raumfahrt, fraunhofer institut für WindenerGie und enerGiesystemtechnik (iWes), inGenieurbüro für neue enerGien (ifne). jaGer, d. et al. (2011): financinG reneWable enerGy in the european enerGy market. brussels, ecofys nl, fraunhofer isi, tu vienna eeG, ernst &younG, european commission (dG enerGy). Weiss, W., et al. (2008): process heat collectors – state of the art. iea heatinG and coolinG proGramme and iea solarpaces proGramme, 2008. international enerGy aGency (iea), paris, france.

collector area above 500 m2 are not so common. however, since 1985, an increasing number of such systems have been installed per year in the eu with a typical annual solar coverage of 15 % in central europe.58,59,60 to get a significant solar share, large storage is needed. the typical solar coverage of such a system including storage is around 50 % today. With seasonal storage, the coverage may be increased to about 80 %.59 another option for domestic heating systems is air collector systems (not described here). the largest markets for air collectors are in north america and asia; these systems have a very small penetration on the european market, though it has been increasing in recent years. process heat

solar thermal use for industrial process heat is receiving some attention for development, although it is hardly in use today. standardized systems are not available because industrial processes are often individually designed. also, solar thermal applications are mostly not capable of providing 100 % of the heat required over a year, so another non-solar heat source would be necessary for commercial use. depending on the temperature level needed, different collectors have been developed to serve the requirements for process heat. flat plates or evacuated tube collectors provide a temperature range up to 80 °c. a large number are available on the market. for temperatures between 80°c and 120°c advanced flat-plate collectors are available, such as with multiple glazing, antireflective coatings, evacuated tubes, and an inert gas filling. other options are flat-plate and evacuated tube collectors with compound parabolic concentrators (cpc). these collectors can be stationary and are generally constructed to concentrate solar radiation by a factor of 1 to 2. they can use most diffuse radiation, which makes them especially attractive for areas with low direct solar radiation. there are a few conceptual designs to reach higher temperatures between 80°c and 180°c, primarily using a parabolic trough or linear concentrating fresnel collectors. these collector types have a higher concentration factor than cpc collectors, are only capable of using direct solar radiation, and have to be combined with sun tracking systems. the collectors especially designed for heat use are most suitable for a temperature range between 150°c and 250 °c. 61 air collector systems for process heat are limited to lower temperatures, being mostly used for to drying purposes (hay, etc.); they are not discussed here. cooling

solar chillers use thermal energy to produce cooling and/or dehumidify the air in a similar way to a refrigerator or conventional air-conditioning. this application is well-suited to solar thermal energy, as the demand for cooling is often greatest when there is most sunshine. solar cooling has been successfully demonstrated. large-scale use can be expected in the future but is still not common. 261

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the option to use solar heat this way makes sense because hot regions require more cooling for comfort. solar thermal cooling is mostly designed as a closed-loop sorption system (see box 10.1). the most common application, however, is a solar absorption cooling unit. the system requires temperatures above 80°c, which means evacuated tube collectors, advanced flat-plate collectors and compound parabolic concentrators. the solar field required for a cooling unit is about 4 m 2 per kW of cooling capacity.

box 10.1 | sorption cooling units

a thermo-chemical refrigerant cycle (sorption) provides cold by either absorption or adsorption cooling. absorption occurs when a gaseous or liquid substance is taken up by another substance, such as the solution of a gas in a liquid. adsorption takes place when a liquid or gaseous substance is bound to the surface of a solid material.

the absorption cooling circle can be described as follows: a liquid refrigerant with a very low boiling point is vaporized at low pressure, withdrawing heat from its environment and therefore providing the desired cooling. the gaseous refrigerant is then absorbed by a liquid solvent, mostly water. the refrigerant and solvent are separated again by adding (renewable) heat to the system, making use of the different boiling points. the gaseous refrigerant is now condensed, released and returned to the beginning of the process. the heat needed in the process can be provided by firing natural gas, combined heat and power plants, solar thermal collectors, etc.

10.6.2 geothermal, hydrothermal and aero-thermal energy

the three categories of environmental heat are geothermal, hydrothermal and aero-thermal energy. Geothermal energy is the energy stored in the earth’s crust, i.e. in rock and subsurface fluids. the main source of geothermal energy is the internal heat flow from the earth’s mantle and core into the crust, which itself is replenished mainly by heat from the decay of radioactive isotopes. at depths of a few meters, the soil is also warmed by the atmosphere. Geothermal energy is available all year round, 24 hours a day, and is independent of climatic conditions. hydrothermal energy is the energy stored in surface waters - rivers, lakes, and the sea. hydrothermal energy is available permanently at temperature level similar to that of shallow geothermal energy. aerothermal energy is the thermal energy stored in the earth’s atmosphere, which originally comes from the sun, but has been buffered by the atmosphere. aero-thermal energy is available uninterruptedly, albeit with variations in energy content due to climatic and regional differences.

262

deep geothermal energy (geothermal reservoirs)

on average, the crust’s temperature increases by 25-30°c per km, reaching around 100°c at 3 km depth in most regions of the world. high temperature fields with that reach over 180°c can be found at this depth in areas with volcanic activity. “deep geothermal reservoirs” generally refer to geothermal reservoirs more than 400m deep, where reservoir temperatures typically exceed 50°c. depending on reservoir temperature, deep geothermal energy is used to generate electricity and/or to supply hot water for various thermal applications, such as for district heat, balneology, etc. temperatures in geothermal reservoirs less that 400m deep are typically below 30°c, which is too low for most direct use applications or electricity production. in these shallow fields, heat pumps are applied to increase the temperature level of the heat extracted from shallow geothermal reservoirs. the use of geothermal energy for heating purposes or for the generation of electricity depends on the availability of steam or hot water as a heat transfer medium. in hydrothermal systems, hot water or water vapor can be tapped directly from the reservoir. technologies to exploit hydrothermal systems are already well established and are in operation in many parts of the world. however, there is limited availability of aquifers with sufficient temperature and water production rate at favorable depths. in europe, high temperature (above 180°c) hydrothermal reservoirs, generally containing steam, are found in iceland and italy. hydrothermal systems with aquifer lowers temperatures (below 180°c) can also be used to produce electricity and heat in other regions. they contain warm water or a watersteam mixture. in contrast to hydrothermal systems, eGs systems do not require a hot aquifer; the heat carrier is the rock itself. they can thus virtually found everywhere. the natural permeability of these reservoirs generally does not allow a sufficient water flow from the injection to the production well, so energy projects require the artificial injection of water into the reservoir, which they do by fracturing rock underground. Water is injected from the surface into the reservoir, where the surrounding rock acts as a heat exchanger. the heated water is pumped back to the surface to supply a power plant or a heating network. While enhanced geothermal systems promise large potentials both for electricity generation and direct use, they are still in the pre-commercialization phase. direct use of geothermal energy

(deep) geothermal heat from aquifers and deep reservoirs can be used directly in hydrothermal heating plants to supply heat demand nearby or in a district heating network. networks provide space heat, hot water in households and health facilities or low temperature process heat (industry, agriculture and services). in the surface unit, hot water from the production well is either directly fed into a heat distribution network (“open loop system”), or heat is

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transferred from the geothermal fluid to a secondary heat distribution network via heat exchangers (“closed loop system”). heating network temperatures are typically in the range 60-100°c. however, higher temperatures are possible if wet or dry steam reservoirs are exploited or if heat pumps are switched into the heat distribution circuit. in these cases, geothermal energy may also supply process heat applications requiring temperatures above 100°c. direct use provides heating and cooling for buildings including district heating, fish ponds, greenhouses, bathing, wellness and swimming pools, water purification/desalination, and industrial and process heat for agricultural products and mineral extraction and drying (ipcc-srren 2012). 62 for space heating, two basic types of systems are used: open and closed loops. open loop (single pipe) systems directly utilize the geothermal water extracted from a well to circulate through radiators (figure 10.31, top). closed loop (double pipe) systems use heat exchangers to transfer heat from the geothermal water to a closed loop that circulates heated freshwater through the radiators (figure 10.31; bottom). alternatively, deep borehole heat exchangers can exploit the relatively high temperature at depths between 300 and

3,000 m (20 – 110°c). heat pumps can be used to increase the temperature of the useful heat, if required. the overall efficiency of geothermal heat use can be raised if several thermal direct-use applications with successive lower temperature levels are connected in series (cascades). for example, dry steam at 250°c can be fed to a cogeneration plant for electricity, the co-generated heat then fed into a district heating network at 80°c, and the waste heat at 40°c used to warm fishing ponds. the main costs for deep geothermal projects are in drilling. simultaneous production of electricity and heat

in many cases, geothermal power plants also produce heat to supply a district heating network. there are two different options for using heat: one where the geothermal fluid is separated into two streams separately used either for power production or to feed the heat network; or a heat exchanger transfers thermal energy from the geothermal fluid to the working fluid, which feeds the turbines. after the heat exchange process, the leftover heat from the geothermal fluid can be used for heating purposes. in both cases, after the electricity production in the turbines waste heat is not captured as it is for cogeneration (chp), but released into the environment.

figure 10.31 | two main types of district heating systems: top, open loop (single pipe system), bottom, closed loop (double pipe system)

source ipcc 2012: special report on renewable energy sources and climate change mitigation. prepared by Working Group iii of the intergovernmental panel on climate change, cambridge university press.

references 62

ipcc 2012: special report on reneWable enerGy sources and climate chanGe mitiGation.

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10.6.3 heat pump technology

a heat pump is a device that transfers heat from one fluid at a lower temperature to another at a higher temperature. thus, it allows heat to be carried from a lower to a higher temperature level. the function of the heat pump may therefore be compared to that of a water pump positioned between two water basins connected to each other but located at different altitudes: water will naturally flow from the higher to the lower basin. it is, however, possible to return water to the higher basin by using a pump, which draws water from the lower one.

a heat pump consists of a closed circuit through which a special fluid (refrigerant) flows. this fluid takes on a liquid or gaseous state according to temperature and pressure conditions. the condenser and the evaporator consist of heat exchangers, i.e. special tubes placed in contact with service fluids (such as air) in which the refrigerant flows. the latter transfer heat to the condenser (the high temperature side) and takes it away from the evaporator (the low temperature side). electric power is required to operate heat pumps, making them an efficient way of electric heating. heat pumps have become increasingly important in buildings but can also be used for industrial process heat. industrial heat pumps (ihps) offer various opportunities to all types of manufacturing processes and operations and use waste process heat as the heat source, deliver heat at higher temperature for use in industrial processes, heating or preheating, or for space heating and cooling in industry. the introduction of heat pumps with operating temperature below 100 °c are state of the art technologies while higher temperature applications still require additional r&d activities.54 heat pumps use the refrigeration cycle to provide heating, cooling and sanitary hot water. they employ renewable energy from ground, water and air to move heat from a relatively low temperature reservoir (the “source”) to the temperature level of the desired thermal application (the “output”). heat pumps commonly use two types of refrigeration cycles: • compression heat pumps use mechanical energy, most commonly electric motors or combustion engines to drive the compressor in the unit. consequently, electricity, gas or oil is used as auxiliary energy. • thermally driven heat pumps use thermal energy to drive the sorption process - either adsorption or absorption - to make ambient heat useful. different energy sources can be used as auxiliary energy: waste energy, biomass, solar thermal energy or conventional fuels. compression heat pumps are most commonly used today; however, thermally driven units are seen as a promising future technology. the “efficiency” of a heat pump is described by the coefficient of power (cop) - the ratio between the annual useful heat output and the annual auxiliary energy references 63

(iea-.etn 2014) application of industrial heat pumps; final report; iea heat pump centre; borås; sWeden; 2014.

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consumption of the unit. in the residential market, heat pumps work best for relatively warm heat sources and lowtemperature applications such as space heating and sanitary hot water. they are less efficient for providing higher temperature heat and can’t be used for heat over 90°c. for industrial applications, different refrigerants can be used to provide heat from 80°c to 90°c efficiently, so they are only suitable for part of the energy requirements of industry. heat pumps are generally distinguished by the heat source they exploit: • Ground source heat pumps use the energy stored in the ground at depths from around hundred meters up to the surface. they are used for deep borehole heat exchangers (300 – 3,000m), shallow borehole heat exchangers (50250m) and horizontal borehole heat exchangers (a few meters deep). • Water source heat pumps are coupled to a (relatively warm) water reservoir of around 10°c, such as wells, ponds, rivers, and the sea. • aero-thermal heat pumps use the outside air as heat source. as outside temperatures during the heating period are generally lower than soil and water temperature, ground source and water source heat pumps typically more efficient than aero-thermal heat pumps. heat pumps require additional energy apart from the environmental heat extracted from the heat source, so the environmental benefit of heat pumps depends on both their efficiency and the emissions related to the production of the working energy. Where the heat pump has low cop and a high share of electricity from coal power plants, for example, carbon dioxide emissions relative to useful heat production might be higher than conventional gas condensing boilers. on the other hand, efficient heat pumps powered with “green” electricity are 100% emission-free solutions that contribute significantly to the reduction of greenhouse gas emissions when used in place of fossil-fuel fired heating systems. box 10.2 | typical heat pump specifications

usually provide hot water or space heat at lower temperatures, around 35°c. example uses: underfloor/wall heating. typical size for space heating a single family house purposes: approx. 5-10 kW thermal typical size for space heating a large office building: >100 kW thermal.

aero-thermal heat pumps do not require drilling, which significantly reduces system costs compared to other types. if waste heat from fossil fuel fired processes is used as heat source for this technology, the heat provided cannot be classified as “renewable” - it becomes merely an efficient way of making better use of energy otherwise wasted.

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[r]evolution

heat pumps for cooling

reversible heat pumps can be operated both in heating and in cooling mode. When running in cooling mode in summer, heat is extracted from the building and “pumped” into the underground reservoir, which is then heated. in this way, the temperature of the warm reservoir in the ground is restored after its exploitation in winter. alternatively, renewable cooling could be provided by circulating a cooling fluid through the relatively cool ground

box 10.3 | district heat networks

heat networks are preferably used in populated areas such as large cities. their advantages include a reduction of local emissions, higher efficiency (in particular with cogeneration), and less need for infrastructures that go along with individual heating solutions. Generally heat from all sources can be used in heat networks. however, some applications like cogeneration technologies have a special need for a secure heat demand provided by heat networks to be able to operate economically. managing the variations in heat supply and demand is vital for high shares of renewables, which is more challenging for space heat and hot water than for electricity. heat networks help even out peaks in demand by connecting a large number of clients, and supply can be adjusted by tapping various renewable sources and relatively cheap storage options. the use of an existing heat network for renewable heat depends on the

before being distributed in a building’s heating/cooling system (“free cooling”). however, this cooling fluid must not be based on chemicals that are damaging to the upper atmosphere, such as hfcs (a strong greenhouse gas) or cfcs (ozonedepleting gas). in principle, high enthalpy geothermal heat might provide the energy needed to drive an absorption chiller. however, only a very limited number of geothermal absorption chillers are in operation world-wide.

competitiveness of the new heat applications or plants. the development of new networks, however, is not an easy task. the factors to assess whether a new heat network is economically competitive compared to other heating and cooling options are: • heat density (heat demand per area) of building infrastructure, depending on housing density and the specific heat demand of the buildings • obligation to connect to the network (leads to higher effective heat density) • existing building infrastructure and newly developed areas, where network installation can be integrated in building site preparation • existence of competing infrastructures such as gas networks • size of the heat network and distance to the remotest client

figure 10.32 | examples for heat pump systems. left : air source collector , right : water source heat pump ( open loop system with two wells )

source

heat pump, middle : ground source heat pump with horizontal

German heat pump association (bWp).

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10.6.4 biomass heating technologies

there is a broad portfolio of technologies for heat production available from biomass, a traditional fuel source. a need for more sustainable energy supply has led to the development of modern biomass technologies. a high variety of new or modernised technologies and technology combinations can serve space and hot water needs and eventually also provide process heat even for industrial processes. biomass can provide a large temperature range of heat and can be transported over long distances, which is an advantage compared to solar thermal or geothermal heat. however, sustainable biomass imposes limits on volume and transport distance. another drawback of bioenergy is exhaust emissions and the risk of greenhouse gas emissions from energy crop cultivation. these facts lead to two approaches to biomass development:

• towards improved, relatively small-scale, decentralized systems for space heat and hot water. • development of various highly efficient and upgraded biomass cogeneration systems for industry and district heating. small applications for space heat and hot water in buildings

in the residential sector, traditional biomass applications have been strongly improved over the last decades for efficient and comfortable space heating and hot water supply. the standard application is direct combustion of solid biomass (wood), for example in familiar but improved firewood stoves for single rooms. for average single homes and small apartment houses, firewood and pellet boilers are an option to provide space heat and hot water. Wood is easy to handle, and standardized quality and pellet systems can be automated along the whole chain; refuelling can then be reduced to a few times a year. automatically fed systems are more easily adaptable to variations in heat demand, such as between summer and winter. another advantage is lower emissions of air pollutants from pellet appliances compared to firewood. 64 pellet heating systems are gaining importance in europe. handfed systems are common for smaller applications below 50 kW. small applications for single rooms (around 5kW capacity) are usually handfed wood stoves with rather low efficiency and low cost. technologies are available for central heating in single and semi-detached houses and are also an option for apartment complexes. Wood boilers provide better combustion with operating efficiencies of 70-85% and fewer emissions than stoves with a typical sizes of 10-50 kW.65,66,67 references 64 65

66 67 68 69 70

Gemis (2011): Globales emissions-modell inteGrierter systeme (Gemis), version 4.6, öko-institut. nitsch, j. et al. (2010): leitstudie 2010 - lanGfristsZenarien und strateGien für den ausbau der erneuerbaren enerGien in deutschland bei berücksichtiGunG der entWicklunG in europa und Global. stuttGart, kassel, teltoW, deutsches Zentrum für luft- und raumfahrt, fraunhofer institut für WindenerGie und enerGiesystemtechnik (iWes), inGenieurbüro für neue enerGien (ifne). Gemis (2011): Globales emissions-modell inteGrierter systeme (Gemis), version 4.6, öko-institut. aebiom (2011b): revieW of investment cost data for biomass heatinG technoloGies. G. a. center. brussels. kaltschmitt, m. et al., eds. (2009): enerGie aus biomasse - GrundlaGen, techniken und verfahren. berlin, heidelberG, sprinGer. iea (2011b): coGeneration and reneWables. international enerGy aGency (iea), paris, france. kaltschmitt, m. et al., eds. (2009): enerGie aus biomasse - GrundlaGen, techniken und verfahren. berlin, heidelberG, sprinGer.

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larger wood boilers can heat large buildings such as apartment blocks, office buildings and other large buildings in service, commerce and industry with space heat and hot water. direct heating technologies

large applications for district or process heat rely on automatic feeding technologies, due to constant heat demand at a defined temperature. direct combustion of biomass can provide temperatures up to 1,000°c, with higher temperatures from wood and lower temperatures from straw, for instance. automatically fed systems are available for wood chips, pellets, and straw. three combustion types are: 68 cogeneration technologies

cogeneration increases the efficiency of using biomass, if the provided heat can be used efficiently. the size of a plant is limited due to the lower energy content of biomass compared to fossil fuels and resulting difficulties in fuel logistics. selection of the appropriate cogeneration technology depends on the available biomass. in several scandinavian countries – with an extraordinarily high potential of forest biomass - solid biomass is already a main fuel for cogeneration processes. finland gets more than 30% and sweden even 70% of its co-generated electricity from biomass. 69 direct combustion technologies

the cogeneration processes can be based on direct combustion types (fixed bed combustion, fluidised bed combustion, pulverised fuel combustion). While steam engines are available from 50 kW electric steam turbines normally cover the range above 2 mWel, with special applications available from 0.5 mW electric. the heat is typically generated at 60- 70% efficiency depending on the efficiency of the power production process, which in total can add up to 90%. 70 thus, small and medium cogeneration plants provide three to five times more heat than power, with local heat demand often being the limiting factor for the plant size. upgraded biomass

there are various conversion technologies available to upgrade biomass products for the use in specific applications and for higher temperatures. common currently available technologies are (upgraded) biogas production and gasification. other technologies such as pyrolysis and the production of synthetic gases and oils are under development. Gasification is especially valuable in the case of biomass with low caloric value and when it includes moisture. partial oxidation of the biomass fuel provides a combustible gas mixture mainly consisting of carbon monoxide (co). Gasification can provide higher efficiency along the whole biomass chain, but at the expense of additional investments in this more sophisticated technology. there are many different gasification systems based on varying fuel input, gasification technology and combination with gas turbines. the literature shows a large cost range for gasification cogeneration plants. assumptions on costs of the gasification processes vary strongly.

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[r]evolution

other upgrading processes are biogas upgrading for exports of natural gas network and the production of liquid biomass, such as plant oil, ethanol or second generation fuels. those technologies can be easily exchangeable with fossil fuels, but the low efficiency of the overall process and energy input needed to produce energy crops are disadvantages for sustainability. 10.6.5 biogas

biogas plants use anaerobic digestion of bacteria for the conversion of various biomass substrates into biogas. this gas mainly consists of methane (a gas of high caloric value), co 2, and water. anaerobic digestion can be used to upgrade organic matter with low energy density, such as organic waste and manure. these substrates usually contain large water contents and appear liquid. “dry” substrates need additional water. liquid residues like wastes and excrements are energetically unused. biogas taps into their calorific potential. the residue of the digestion process is used as a fertilizer, which has higher availability of nitrogen and is more valuable than the input substrates. 71 methane is a strong greenhouse gas, so biogas plants need airtight covers for the digestate to maintain low emissions. 72 residues and wastes are preferable for biogas compared with energy crops such as corn silage, which require energy and fertilizer inputs while growing and thus create greenhouse gas emissions. biogas plants usually consist of a digester for biogas production and a cogeneration plant. plants vary in size and are normally fed by a mixture of substrates for example manure mixed with maize silage, grass silage, other energy crops and/or organic waste. 73 normally biogas is normally used in cogeneration. in Germany, the feed-in tariff means biogas production currently is mostly for power. the majority of biogas plants are on farms in rural areas. small biogas plants often use the produced heat for local space heating and process heat, such as for drying processes. larger biogas plants need access to a heat network to make good use of all the available heat. however, network access is often not available in rural areas, so there is still untapped potential of heat consumption from biogas. monitoring of German biogas plants showed that 50% of available heat was actually wasted.74 the conditioning and enriching of biogas and subsequent export to the gas network has been promoted lately and should become an option to use biogas directly at the location of heat demand. upgrading technologies for biomass do bear the risk of additional methane emissions, so tight emission standards are necessary to achieve real reductions in greenhouse gas emissions. 75

greenpeace has a very strict policy in order to use only sustainable bioenergy in future energy systems. guidelines for the future use of bioenergy are documented in chapter 8

10.6.6 storage technologies

as the share of electricity provided by renewable sources increases around the world the technologies and policies required to handle their variability is also advancing. along with the grid-related and forecasting solutions discussed in chapter 3, energy storage is a key part of the energy [r]evolution. once the share of electricity from variable renewable sources exceeds 30-35%, energy storage is necessary in order to compensate for generation shortages or to store possible surplus electricity generated during windy and sunny periods. today storage technology is available for different stages of development, scales of projects, and for meeting both shortand long-term energy storage needs. short-term storage technologies can compensate for output fluctuations that last only a few hours, whereas longer term or seasonal storage technologies can bridge the gap over several weeks. short-term options include batteries, flywheels, compressed air power plants and pump storage power stations with high efficiency factors. the later is also used for long term storage. perhaps the most promising of these options is electric vehicles (evs) with vehicle-to-Grid (v2G) capability, which can increase flexibility of the power system by charging when there is surplus renewable generation and discharging while parked to take up peaking capacity or ancillary services to the power system. vehicles are often parked close to main load centres during peak times (e.g., outside factories) so there would be no network issues. however battery costs are currently very high and significant logistical challenges remain. seasonal storage technologies include hydro pumped storage and the production of hydrogen or renewable methane. While the latter two options are currently in the development with several demonstration projects mainly in Germany, pumped storage has been in use around the world for more than a century.

references 71 72

kaltschmitt, m. et al., eds. (2009): enerGie aus biomasse - GrundlaGen, techniken und verfahren. berlin, heidelberG, sprinGer. pehnt, m. et al. (2007): biomasse und effiZienZ - vorschläGe Zur erhöhunG der enerGieeffiZienZ von §8 und §7-anlaGen im erneuerbare-enerGien-GesetZ. arbeitspapier nr. 1 im rahmen des projektes “enerGiebalance – optimale systemlösunGen für erneuerbare enerGien und enerGieeffiZienZ”. heidelberG, institut für enerGie und umWeltforschunG heidelberG Gmbh (ifeu). iea (2007): reneWables for heatinG and coolinG. international enerGy aGency (iea), paris, france. nitsch, j. et al. (2010): leitstudie 2010 - lanGfristsZenarien und strateGien für den ausbau der erneuerbaren enerGien in deutschland bei berücksichtiGunG der entWicklunG in europa und Global. stuttGart, kassel, teltoW, deutsches Zentrum für luft- und raumfahrt, fraunhofer institut für WindenerGie und enerGiesystemtechnik (iWes), inGenieurbüro für neue enerGien (ifne). dbfZ (2010): monitorinG Zur WirkunG des erneuerbare-enerGien-GesetZes (eeG) auf die entWicklunG der stromerZeuGunG aus biomasse (unveröffentlichter entWurf). leipZiG, deutsches biomasseforschunGsZentrum. Gärtner, s. et al. (2008): optimierunGen für einen nachhaltiGen ausbau der bioGaserZeuGunG und nutZunG in deutschland, materialband e: ökobilanZen. heidelberG, institut für enerGie- und umWeltforschunG.

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pumped storage

renewable methane

pumped storage is the largest-capacity form of grid energy storage now available and currently the most important technology to manage high shares of wind and solar electricity. it is a type of hydroelectric power generation that stores energy by pumping water from a lower elevation reservoir to a higher elevation during times of low-cost, off-peak electricity and releasing it through turbines during high demand periods. While pumped storage is currently the most cost-effective means of storing large amounts of electrical energy on an operating basis, capital costs and appropriate geography are critical decision factors in building new infrastructure. losses associated with the pumping and water storage process make such plants net consumers of energy; accounting for evaporation and conversion losses, approximately 70-85% of the electrical energy used to pump water into the elevated reservoir can be recaptured when it is released.

both gas plants and cogeneration units can be converted to operate on renewable methane, which can be made from renewable electricity and used to effectively store energy from the sun and wind. renewable methane can be stored and transported via existing natural gas infrastructure, and can supply electricity when needed. Gas storage capacities can close electricity supply gaps of up to two months, and the smart link between power grid and gas network can allow for grid stabilisation. expanding local heat networks, in connection with power grids or gas networks, would enable the electricity stored as methane to be used in cogeneration units with high overall efficiency factors, providing both heat and power. 76 there are currently several pilot projects in Germany in the range of one to two- megawatt size, but not in a larger commercial scale yet. if those pilot projects are successful, a commercial scale can be expected between 2015 and 2020. however, policy support, to encourage the commercialisation of storage is still lacking.

figure 10.33 | overview storage capacity of different energy storage systems

figure 10.34 | renewable (power) (to) methane renewable gas storing renewable power as renewable as

natural gas by linking electricity and natural gas networks methan

10,000

100

Discharge time [hours]

electricity network

sng

1,000 phs

• for heat • for transport

winD

caes

chp, tUrbines

solar h2

batteries

natUral gas network

other renewables

0.1

fly wheels

0.01

gas storage

power storage power generation

100 twh

10 twh

1 twh

100 gwh

10 gwh

1 gwh

100 mwh

10 mwh

1 mwh

100 kwh

10 kwh

1 kwh

0.001

source fraunhofer institut, 2010.

H 2O • fossil fuels • biomass, waste • atmosphere co2

O2 H2

electrolysis h2 tank

co2

methanation

co2 tank

renewable power methane plant

references 76

(f-iWs 2010) fraunhofer iWs, erneuerbares methan kopplunG von strom- und GasnetZ m.sc. mareike jentsch, dr. michael sterner (iWes), dr. michael specht (ZsW), tu chemnitZ, speicherWorkshop chemnitZ, 28.10.2010.

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ch4 h 2o

windmethane solarmethane

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[r]evolution

battery storage

there are numerous battery technologies on the market and the increasing demand for electric vehicles triggered the battery development significantly of the past decade. the latest announcement of the us american company tesla to build up a large scale battery manufaction plant will most likely result in increased competition among the battery industry and reduced prices. especially lithium batteries are currently under discussion and a new generation of large scale lithium-metal and lithiumion-batteries (lib) as well as small scale application such as tesla’s “powerWall” will increasingly complement renewable power generation. besides that, mobile energy storage devices form the basis not only for future oriented drive systems such as vehicles with hybrid drive and all electrically driven vehicles but also hydrogen storage and fuel cell technologies. battery systems like lithium-sulfur and lithiumair have a great potential to reach the highest capacity and energy density values (dlr-Wagner). 77 in order to increase battery safety, reliability and to reduce costs partly through

economies of scale, battery research and development activities have significantly expanded worldwide. many energy experts see new battery technology in combination with low cost solar photovoltaic power generation as a potential disruptive technology which can change future energy markets dramatically.

storage technologies – the cascade approach

there is no “one-size-fits-all” technology for storage. along the entire supply and demand chain, different storage technologies are required to cover the exact needs in regard to storage time – from second reserve for frequency stability to seasonal storage of several months. a cascade of different storage technologies is required to support the local integration of power generation from variable renewable energy (vre) in distribution networks, support the grid infrastructure to balance vre power generation, and support self-generation and self-consumption of vre by customers. figure 30 shows a whole range of storage technologies.

figure 10.35 | potential locations and applications of electricity storage in the power system

thermal storaGe 1 3

bulk storaGe

distributed storaGe

commercia l storaGe

balancinG storaGe

residential storaGe

source irena – storage 2015.78

references 77 78

(dlr-WaGner 2015) dr. rer.nat. norbert WaGner; http://WWW.dlr.de/tt/en/desktopdefault.aspx/tabid-7197/ (irena – storaGe 2015) reneWables and electricity storaGe – a technoloGy roadmap; international reneWable enerGy aGency (irena) irena innovation and technoloGy centre; rober t-schuman-platZ 3; 53175 bonn; Germany; june 2015

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e n e r gy e f f i c i e n cy – m o r e w i t h l e s s methodology for the energy demand projections

energy consumption in the year 2012

reference demand scenario

efficiency measures and potentials

efficiency pathways of the energy [r]evolution development of energy intensities

“

smart use of renewable energy makes economic sense”

image the dark squares that make up the checkerboard pattern in this image are fields of a sort—fields of seaweed. along the south coast of south korea, seaweed is often grown on ropes, which are held near the surface with buoys. this technique ensures that the seaweed stays close enough to the surface to get enough light during high tide but doesn’t scrape against the bottom during low tide.

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using energy efficiently is cheaper than producing new energy from scratch and often has many other benefits. an efficient clothes washing machine or dishwasher, for example, uses less power and saves water too. efficiency in buildings doesn’t mean going without – it should provide a higher level of comfort. for example, a well-insulated house will feel warmer in the winter, cooler in the summer and be healthier to live in. an efficient refrigerator is quieter, has no frost inside or condensation outside, and will probably last longer. efficient lighting offers more light where you need it. efficiency is thus really better described as ‘more with less’. there are very simple steps every to efficiency both at home in business and industries, through updating or replacing separate systems or appliances, that will save both money and energy. but the biggest savings don’t come from incremental steps but from rethinking the whole concept ‘the whole house’, ‘the whole car’ or even ‘the whole transport system’. in this way, energy needs can often be cut back by four to ten times. in order to find out the global and regional energy efficiency potential, the dutch institute ecofys developed energy demand scenarios for the Greenpeace energy [r]evolution analysis in 2008, which have been updated by the university of utrecht for the 2012 scenario edition (Graus et al. 2012). 1 for the 2015 edition, the German aerospace center (dlr) further developed and specified the energy demand pathways for the power, heating, industry, transport and other sectors via energy intensity indicators for all regions. these scenarios cover energy demand over the period 20122050 for ten world regions. in contrast to a reference scenario, based on the iea World energy outlook 2014 (iea Weo 2014) 2, a low energy demand scenario for energy efficiency improvements has been defined taking into account historic trends, estimated technical efficiency potentials and regional differences. the efficiency scenario is based on the best technical energy efficiency potentials taking into account implementation constraints including costs and other barriers. the resulting demand structures of the updated energy [r]evolution scenarios are summarised below. this chapter focuses on stationary sectors and processes, information about efficiency measures, technologies and demand scenarios for the transportation sector can be found in chapter 12.

11.1 methodology for the energy demand projections 11.1.1 step 1: definition of a reference demand scenario

in order to estimate potentials for energy-efficiency improvement in 2050 a detailed reference scenario is required that projects the development of energy demand when current trends continue. in the World energy outlook 2014 “current policies” scenario (iea Weo 2014) only currently adopted energy and climate change policies are implemented. technological change including efficiency improvement is slow but substantial and mainly triggered by increased energy prices. the reference scenario covers energy demand development in the period 2012-2050 for ten world regions and three sectors: • transport • industry • other (also referred to as “buildings and agriculture”). Within the industry and other sectors a distinction is made between electricity demand and fuel and heat demand. heat demand mainly consists of district heating from heat plants and from combined heat and power plants. fuel and heat demand is referred to as ‘fuel demand’ for in the figures that follow. the energy demand scenarios focus only on energyrelated fuel, power and heat use. feedstock consumption in industries is thus excluded from the analysis. total final consumption data in Weo includes non-energy use. by assuming that the share of non-energy use remains the same as in the base year 2012, we determine the energy-related fuel use beyond 2012. 11.1.2 step 2: development of low energy demand scenarios

the low energy demand scenarios are based on literature studies and new calculations. the scenarios take into account: • the implementation of best practice technologies and a certain share of emerging technologies. • no behavioral changes or loss in comfort levels. • no structural changes in the economy, other than occurring in the reference scenario. • equipment and installations are replaced at the end of their (economic) lifetime, so no early retirement.

references 1

(Graus et al. 2012); enerGy demand projections for enerGy [r]evolution 2012; Wina Graus; katerina kermeli; utrecht university, march 2012; commissioned by: Greenpeace international and dlr; http://WWW.enerGyblueprint.info/1432.0.html (iea Weo 2014); World enerGy outlook 2014, international enerGy aGency.

the development pathways are based on the current worldwide energy use per sector and subsector and the development of energy intensities in recent years, according to the Weo scenarios and under the assumption of technical potentials according to (Graus et al. 2012). furthermore, the low energy demand scenarios aim for a convergence of

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energy consumption pattern in consistent to the convergence assumed in the scenarios. figure final energy demand in the world sectors in the base year 2012.

the different world regions of economic development 11.1 shows a breakdown of by the most important sub-

efficiency measures and potentials in the transport sector were described by the dlr institute of vehicle concepts in 2012 and updated and expanded in 2014 in commission of Greenpeace (dlr 2015). 3 the results are used as a basis for developing the energy [r]evolution scenarios and documented in chapter 12. 11.2 energy consumption in the year 2012 the following figures provide a short overview on the energy consumption pattern worldwide and per world regions in 2012 as provided by the iea energy balances of 2014. 4 figure 11.1 shows the final energy consumption worldwide distinguished by energy carriers and sub-sectors.

Worldwide, industry consumes about 33% of total final energy demand on average in 2012 (excluding non-energy use). the share in africa is lowest with 16%, the share in china is highest with 52%. energy consumption in the residential sector (included in other sectors) add up to 25% of total final energy consumption worldwide. figure 11.2 shows a breakdown of final energy demand by sub sector in industry worldwide for the base year 2012. the largest energy consuming sectors in industry are chemical and petrochemical industry, iron and steel and nonmetallic minerals. together the sectors consume about 45% of industrial energy demand. since these three sectors are relatively large we look at them in detail. also we look at aluminium production in detail, which is in the category of non-ferrous metals because the share of aluminium production makes up more than 10% of total industrial energy demand in 2012 (iea-Weo 2014). for all sectors, we look at implementing best practice technologies, increased recycling and increased material efficiency. Where possible, the potentials are based on specific energy consumption data in physical units (mj/tonne steel, mj/tonne aluminium etc.).

figure 11.1 | final energy demand for the world by sub sector and fuel source in 2012 120

figure 11.2 | breakdown of final energy consumption in 2012 by sub sector for industry 100% 90%

100

80% 70%

60% PJ

50% 40%

30% 20%

10% 0 INDUSTRY

TRANSPORT

RESIDENTIAL

OTHER

COMMERCIAL

2012

PUBLIC SERVICES

HEAT

NATURAL GAS

ELECTRICITY

OIL

RENEWABLES

COAL

source iea Weo 2014.

NON-SPECIFIED (INDUSTRY)

MACHINERY

TEXTILE AND LEATHER

TRANSPORT EQUIPMENT

CONSTRUCTION

NON-METALLIC MINERALS

WOOD AND WOOD PRODUCTS

NON-FERROUS METALS

PAPER, PULP AND PRINT

CHEMICAL AND PETROCHEMICAL

FOOD AND TOBACCO

IRON AND STEEL

MINING AND QUARRYING

source iea Weo 2014.

references 3 4

(dlr 2015); project report; alternative transport technoloGies for meGacities; German aerospace center (dlr), institute of vehicle concepts (dlr-fk), stuttGart, Germany; 27 february 2015. (iea 2014): international enerGy aGency (iea), paris: enerGy balances of oecd countries and enerGy balances of non-oecd countries, 2014 edition. http://data.iea.orG

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90% 80% 70% 60% 50% 40% 30% 20% 10%

AFRICA

MIDDLE EAST

LATIN AMERICA

OTHER ASIA

CHINA

INDIA

EASTER EUROPE/EURASIA

OECD EUROPE

0 WORLD

the residential sector has the largest end-use for fuels and heat, see figure 11.5: its share ranges from 44% in oecd asia oceania to 91% in africa.

100%

OECD ASIA OCEANIA

fuels and heat use represent the largest share of total final energy use in this sector, see figure 11.4. the share ranges from 51% for oecd north america to 95% for africa.

figure 11.4 | breakdown of final energy demand in 2012 for electricity and fuels/heat in other sectors

OECD NORTH AMERICA

energy consumed in buildings and agriculture (summarized as other sectors) represents 40% of global energy consumption in 2012. in most regions, the share of residential energy demand is larger than the share of commercial and public services energy demand (except in oecd asia oceania). since energy use in agriculture is relatively small (globally less than 5% of total final energy demand), we do not look at this sector in detail but assume the same energy saving potentials as in residential and commercial combined.

ELECTRICITY FUELS AND HEAT

source iea Weo 2014.

AFRICA

MIDDLE EAST

LATIN AMERICA

OTHER ASIA

0 CHINA

INDIA

10%

EASTER EUROPE/EURASIA

20%

10%

OECD EUROPE

20%

OECD ASIA OCEANIA

30%

OECD NORTH AMERICA

40%

30%

WORLD

40%

AFRICA

50%

MIDDLE EAST

60%

50%

LATIN AMERICA

60%

OTHER ASIA

70%

CHINA

80%

70%

INDIA

80%

EASTER EUROPE/EURASIA

90%

OECD EUROPE

100%

90%

OECD ASIA OCEANIA

100%

OECD NORTH AMERICA

figure 11.5 | breakdown of fuel and heat use in other sectors in 2012

WORLD

figure 11.3 | breakdown of electricity use in other sectors in 2012

NON-SPECIFIED

COMMERICIAL AND PUBLIC SERVICES

NON-SPECIFIED

COMMERICIAL AND PUBLIC SERVICES

FISHING

RESIDENTIAL

FISHING

RESIDENTIAL

AGRICULTURE AND FORESTRY

source iea Weo 2014.

AGRICULTURE AND FORESTRY

source iea Weo 2014.

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While residential buildings use a bigger share of fuel and heat, for electricity, the consumption is more evenly spread over the subsector of “commerce and public services” and residential. Globally, 48% of electricity is used in residential buildings and 40% in commerce and public services (also referred to as services). the use of electricity in the services sector strongly depends on the region and ranges from 16% in india to 55% in oecd asia oceania, see figure 11.6. the breakdown of electricity use per type of appliance is different per region. in the energy [r]evolution scenario, a convergence is assumed for the different types of electricity demand per region in 2050. based on data in the literature 5, the following breakdown of electricity use per type is used as default if no specific regional information is available: • space heating 10%

11.3 reference demand scenario figure 11.7 shows the reference scenario for final energy demand for the world per sector derived from the iea Weo 2014. Worldwide final energy demand is expected to grow by 65%, from 327 exajoule (ej) in 2012 to more than 538 ej in 2050. the electricity demand has the largest relative growth of 120% in industry and 130% in other sectors. fuel demand in other sectors is expected to grow slowest from 92 ej in 2012 to 116 ej in 2050.

• hot water 10% • lighting 20% • ict and home entertainment (he) 12% • other appliances 30% • air conditioning 18%

figure 11.6 | breakdown of electricity use by sub sector in other sectors in 2012

figure 11.7 | final energy demand in the reference scenario per sector worldwide 600,000

100% 90%

500,000

80% 70%

400,000 PJ/a

60% 50%

300,000

40% 200,000

30% 20%

100,000

10% 0 AFRICA

MIDDLE EAST

LATIN AMERICA

OTHER ASIA

CHINA

INDIA

EASTER EUROPE/EURASIA

OECD EUROPE

OECD ASIA OCEANIA

OECD NORTH AMERICA

0 WORLD

the trend is moving in the wrong direction: energy demand continues to grow for appliances, lighting, and a large array of electrical and fossil fuel-powered equipment, despite significant progress on labelling and mandatory minimum energy performance standards (meps). market penetration of major appliances has increased significantly in emerging markets, and plug loads from electrical devices and network usage continue to grow in all markets, resulting in energy consumption growth of over 50% from 2000 to 2012 (iea etp 2015).

NON-SPECIFIED

COMMERICIAL AND PUBLIC SERVICES

FISHING

RESIDENTIAL

AGRICULTURE AND FORESTRY

source iea Weo 2014. references 5

iea (2007) enerGy use in the neW millennium – trends in iea countries. oecd/international enerGy aGency. ipcc (2007) fourth assessment report. WorkinG Group iii: mitiGation of climate chanGe. cambridGe university press. iea (2009) enerGy technoloGy transitions for industry: strateGies for the next industrial revolution. paris, france: oecd/iea, 2009.

274

2012

2015

2020

TRANSPORT INDUSTRY

- ELECTRICITY

INDUSTRY

- ELECTRICITY

2025

2030

2035

2040

OTHERS

- FUELS

OTHERS

- ELECTRICITY

source iea Weo 2014 / dlr calculations for reference case.

2045

2050

energy

[r]evolution

in the reference scenario, final energy demand in 2050 will be largest in china (112 ej), followed by oecd north america (82 ej) and india (61 ej). final energy demand in oecd asia oceania, middle east and latin america will be lowest (21 ej and 36 ej respectively).

figure 11.9 | final energy demand per capita in the reference scenario 160

figure 11.9 shows the development of final energy demand per capita per region in the reference scenario.

120 100 GJ/capita

there would still be large differences between regions for final energy demand per capita in 2050 in the reference scenario. energy demand per capita is expected to be highest in oecd north america and eastern europe/eurasia (135 and 132 Gj/capita respectively), followed by oecd asia oceania and middle east (104 and 103 Gj/capita respectively). final energy demand in africa, india, other non-oecd asia, and latin america is expected to be lowest, ranging from 19-58 Gj/capita.

140

80 60 40 20 0

figure 11.10 gives the reference scenario for final energy demand in industries in the period 2012-2050.

2012

as can be seen, the energy demand in chinese industries is expected to be huge in 2050 and amount to 54 ej. the energy demand in all other regions together is expected to be 133 ej, meaning that china accounts for 29% of worldwide energy demand in industries in 2050.

2015

2020

2025

2030

2035

2040

AFRICA

INDIA

MIDDLE EAST

EASTERN EUROPE/EURASIA

LATIN AMERICA

OECD EUROPE

OTHER ASIA

OECD ASIA OCEANIA

CHINA

OECD NORTH AMERICA

2045

2050

source iea Weo 2014 / dlr calculations for reference case.

figure 11.10 | energy demand in industry in the reference scenario per region

600,000

500,000

400,000

400,000 PJ/a

PJ/a

figure 11.8 | final energy demand in the reference scenario per region

300,000

200,000

100,000

2012

2015

2020

2025

2030

2035

2040

2045

2050

2012

2015

2020

2025

2030

2035

2040

AFRICA

INDIA

AFRICA

INDIA

MIDDLE EAST

EASTER EUROPE/EURASIA

MIDDLE EAST

EASTERN EUROPE/EURASIA

LATIN AMERICA

OECD EUROPE

LATIN AMERICA

OECD EUROPE

OTHER ASIA

OECD ASIA OCEANIA

OTHER ASIA

OECD ASIA OCEANIA

CHINA

OECD NORTH AMERICA

CHINA

OECD NORTH AMERICA

source iea Weo 2014 / dlr calculations for reference case.

2045

2050

source iea Weo 2014 / dlr calculations for reference case.

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world energy [r]evolution a sustainable world energy outlook

figure 11.11 shows that energy demand in buildings and agriculture in 2050 is highest in oecd north america (33 ej), followed by china (32 ej) and oecd europe (29 ej). oecd asia oceania, latin america and middle east have the lowest energy demand for buildings and agriculture, ranging from 9-11 Gj. the share of fuel and electricity use by buildings and agriculture in total energy demand in 2012 and 2050 are shown in figure 11.12. india and africa have the highest share of buildings and agriculture in total final energy demand today. until 2050, a sharp decrease is expected in india. Globally, it is expected that electricity use in this sector will be bigger in 2050 than in 2012 (16% instead of 12%) and fuel use will be smaller (22% instead of 28%).

figure 11.11 | energy demand in other sectors in the reference scenario per region 35,000 30,000 25,000 20,000 PJ/a

in the reference scenario, energy demand in buildings and agriculture is forecast to grow considerably (see figure 11.11).

15,000 10,000 5,000 0

2012

2015

2020

2025

2030

2035

2040

AFRICA

INDIA

MIDDLE EAST

EASTERN EUROPE/EURASIA

LATIN AMERICA

OECD EUROPE

OTHER ASIA

OECD ASIA OCEANIA

CHINA

OECD NORTH AMERICA

2045

source iea Weo 2014 / dlr calculations for reference case.

figure 11.12 | share electricity and fuel consumption by other sectors in total final energy demand in 2012 and 2050 in the reference scenario 70% 60% 50%

40% 30% 20% 10%

2012 FUELS

2050 FUELS

2012 ELECTRICITY

2050 ELECTRICITY

source iea Weo 2014 / dlr calculations for reference case.

276

AFRICA

MIDDLE EAST

LATIN AMERICA

OTHER ASIA

CHINA

INDIA

EASTERN EUROPE/EURASIA

OECD EUROPE

OECD ASIA OCEANIA

OECD NORTH AMERICA

WORLD

2050

energy

[r]evolution

11.4 efficiency measures and potentials 11.4.1 efficiency measures in industry

the overall technical efficiency potentials are estimated after identifying the most significant energy-efficiency improvements. in the reference scenario, some of these energy-efficiency improvements have already been implemented (autonomous and policy induced energy-efficiency improvement). this baseline was complemented by a most efficient development pathway assuming all known and characterized efficiency measures in the industry sector as being implemented. the benchmarking of the industry sector’s energy use can provide valuable insights regarding energy efficiency potentials. energy efficiency indicators (eeis) differ significantly between countries and sectors as a result of differences in resource availability, energy prices, plant size, and the age of capital stock, local factors, capital costs, awareness, opportunity costs and government policies. international energy statistics, which are the basis of the eei approach, are subject to uncertainties however. international benchmark studies show large differences for energy intensity on a country level for the iron and steel, chemical and pulp and paper industry. large energy savings potentials were found in the range of 20-30% on average. this section documents a special survey about industry efficiency potential commissioned by Greenpeace international in 2013

(uni utrecht 2013). 6 unfortunately, there are only very few publications about energy efficiency potentials for various subsectors of the global industry. thus, consistent data is sometimes up to 10 years old, and there is a need for more indepth research. even the Global energy assessment report – published in 2012 – refers to data from 2007 and 2005. iron and steel

most sectors in manufacturing industry produce a range of products, so it is generally not possible to apply a simple indicator of energy efficiency in energy use per tonne of product. instead, an aggregate indicator, the energy efficiency index (eei) is used. a decrease of the eei means that the energy use per unit of product was reduced. figure 11.13 shows the development of the energy efficiency index for the iron and steel industry for G8+5 countries. for all countries together, the energy efficiency improvement amounted to 9 % between 2000 and 2005 (1.8 per cent per year). it is striking that in some countries (such as south africa), energy efficiency deteriorated, which may be caused by the strong increase in steel demand, leading companies to take less efficient plants into operation again. also remarkable is the strong progress in energy efficiency in china (7.4%/a) and india (7.9%/a), most likely through the rapid expansion of production capacity with relatively efficient technology (reeep, 2008).7

figure 11.13 | energy efficiency index for iron and steel industry

primary energy use per capita

100

GJ/capita

1990

2000

1995

2005

SOUTH AFRICA

MEXICO

INDIA

CHINA

BRAZIL

USA

RUSSIA

JAPAN

ITALY

GERMANY

FRANCE

CANADA

source reeep, 2008.

references 6

(uniutrecht 2013); backGround material about the enerGy intensive industries in the 30 % debate; for internal use Within Greenpeace; Wina Graus (uu); mirjam harmelink (harmelink consultinG); dian phylipsen (phylipsen climate chanGe consultinG); mariëlle corsten (uu); june 2013. (reeep 2008) Global status report on enerGy efficiency 2008.

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world energy [r]evolution a sustainable world energy outlook

energy improvement efficiency potential index

0.70

29.8

japan

2,130

1,917

0.90

10.0

china

3,740

2,975

0.80

20.5

saudi arabia

1,115

917

0.82

17.8

Germany

1,157

1,044

0.90

9.8

netherlands

618

508

0.82

17.8

france

654

582

0.88

11.0

braZil

577

478

0.83

17.2

490

460

0.94

6.2

1,091

910

0.84

15.8

chinese taipei

741

599

0.81

19.2

italy

389

365

0.94

6.2

28,819

23,682

0.82

17.8

worlD

70 60 50 40 30

28 GJ/tonne

20 10 0

1995

INDIA

4,887

CHINA

6,862

BRAZIL

usa

india

figure 11.14 | specific energy consumption in ammonia (nh 3) production in 1995 and 2005

CANADA

reported bpt energy use calculated pj energy use

the specific energy use for ammonia production (including feed stocks) for G8+5 is given in figure 11.14. G8 countries for which data are available show a slow decline in specific energy use in 2005 in comparison to 1995. the average progress (weighted according to production volumes) is 15 % over the period from 1995-2005 (1.7 % per year). also, in this case progress in developing countries (brazil and india) is much faster. the specific energy consumption in china is highest and reveals a large efficiency improvement potential.

RUSSIA

table 11.1 | energy efficiency of chemical and petrochemical industry

ammonia production

GJ/tonne

table 11.1 shows an energy efficiency index of chemical industry on country level. note that the eei is inverted in comparison to the eei for the iron and steel industry, here a higher eei means higher energy efficiency. the eei implies a global average energy savings potential in the chemical industry of 18% by implementing best practice technology.

due to the high diversity in terms of products produced in the chemical industry it is worthwhile to look into energy efficiency indicators for different products; such as the following example of energy efficiency potential for the production of ammonia.

USA

chemicals

values range from 0.7 for the us to 0.94 for italy. Generally a determining factor in the energy efficiency index is the age of plants, where older plants are less efficient than newer plants. however, retrofits can invalidate this rule of thumb. a global analysis indicates that chemical plants built in the 1970s are the least efficient. the 1950 â&#x20AC;&#x201C; 60s production plants had a significant amount of upgrading, especially after the 1973 oil price crisis, and show relatively good performance (iea, 2007).

figure 11.13 indicates that iron and steel plants in japan are most efficient, followed by plants in Germany. among the included eu countries, the eeis for the uk and italy are relatively high and imply high overall energy efficiency improvement potentials in the range of 35-45% on average. significant differences exist in energy efficiency and co 2 emission intensity of steel production among countries and production plants. these differences can, partly, be explained by variations in the quality of the resources and the cost of energy (iea, 2008a). 8 low energy efficiencies in some countries reflect traditionally very low energy prices and decreasing production volumes. however, in many countries production has increased in recent years and energy prices have risen substantially, already resulting in energy efficiency improvements (iea, 2008a). furthermore, factors such as good housekeeping, process control and level of waste heat recovery may also explain the differences in energy and co 2 emission intensity.

2005

note the dotted line indicates the best-practice level for ammonia (nh3) production in 1995 and 2005. source reeep, 2008.

source iea, 2007. references 8

278

(iea 2008a) World trends in enerGy use and efficiency â&#x20AC;&#x201C; key insiGhts from iea indicator analysis, international enerGy aGency, paris.

energy

[r]evolution

pulp and paper industry

energy efficiency improvement potentials and barriers

table 11.2 shows an energy efficiency index (eei) for the pulp and paper industry for a selection of countries. the eei is based on best practice values for pulp and paper production and actual energy use in countries for pulp and paper production (both in Gj/ton). an eei of 1.4 means that energy use of pulp and paper production is 40% above best practice, so this implies a savings potential by implementing best practice technology of 40% in comparison to current energy use.

the largest potential for energy efficiency improvement can be found when replacing older plants by new capacity. the long term potential is at least 20-30% (on average), based on implementing Best Available Techniques (bat), and can increase in the future by emerging technologies that become available. in general, high energy efficiency improvement rates in industry require timely retirement of old/less efficient capacity. retrofitting a 30-year-old plant so it can last another 20 years is disadvantageous from an energy efficiency point of view because the largest improvement potential is available when building new capacity, where plants can be completely redesigned.

based on the eei in table 11.2 japan and south korea are most efficient in terms of pulp and paper production, whereas the us and canada have the lowest energy efficiency. over the last decade, the south korean paper industry has invested heavily in relatively efficient capacity expansion (iea, 2007). 9 canada’s comparatively low energy efficiency, on the other hand, may be attributed to a high level of energy use in older newsprint mills. also cheap hydroelectric power and the use of wood waste with low efficiency could explain the low eei in canada (iea, 2007).

table 11.2 | energy efficiency index of pulp and paper production eei japan

0.9-1.2

south korea

1.0-1.2

many studies show negative costs for most energy efficiency measures in industry, meaning that the payback time of measures is below their lifetime. it should be noted though that not all steps taken are necessarily profitable from a company’s perspective although most measures payback within their lifetime. investment criteria in terms of desired payback times, restrictions to the height of up-front capital costs and opportunity costs in the end determine the attractiveness of measures. furthermore, companies can be very hesitant to implement measures that might (temporarily) reduce plant reliability. the most important barriers that can prevent energy efficiency and emission reduction measures from being implemented and inhibit investment in technologies that are both energy efficient and economically efficient include: • capital goods have not yet been fully depreciated; • the lack of access to capital for investments in energy efficiency measures and emission reduction measures;

austria

1.0

spain

1.1

belGium

1.2

finland

1.2

france

1.2

Germany

1.2

italy

1.3

sWeden

1.4

usa

1.7

space heating

canada

2.0

Globally, buildings accounted for 32% (118.6 ej) of final energy consumption in 2012 and 53% of global electricity consumption (iea etp 2015). 10 energy-efficiency improvement for space heating is indicated by the energy demand per m 2 floor area per heating degree day (hdd). heating degree day is the number of degrees that a day’s average temperature is below 18 o celsius. typical current heating demand for dwellings in oecd countries is 70-120 kj/m 2/hdd (based on iea, 2007), but those with better efficiency consume below 32 kj/m 2/hdd. 11 the european

source kuramochi, 2006.

references 9 10 11

(iea 2007). trackinG industrial enerGy efficiency and co2 emissions. international enerGy aGency, paris, france. (iea etp 2015); enerGy technoloGy perspectives 2015 – trackinG clean enerGy process; international enerGy aGency; june 2015. this is based on a number of Zero-enerGy dWellinG in the netherlands and Germany, consuminG 400-500 m3 natural Gas per year, With a floor surface betWeen 120 and 150 m2. this results in 0.1 Gj/m2/yr and is converted by 3100 heatinG deGree days to 32 kj/m2/hdd.

• investments in other projects within the company are considered more important or more efficient. literature provides ample empirical evidence for the existence of such barriers in the industry sector. 11.4.2 efficiency measures in buildings

a summary of possible energy saving measures for each of the three types of fuel/heat use is provided here.

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union, which has made the most progress compared to other regions, requires member countries to include cost optimality as a criterion when developing building codes. france, for example, has enacted a building code that limits space heating, water heating, cooling and lighting energy to 50 kWh/m 2 or less (iea etp 2015). an example of a household with low energy use is given in figure 11.15. technologies to reduce energy demand of new dwellings are : 12 • triple-glazed windows with low-emittance coatings. these windows reduce heat loss to 40% compared to windows with one pane. the low-emittance coating prevents energy waves in sunlight coming in and thereby reduces cooling need.

• insulation of roofs, walls, floors and basement. proper insulation reduces heating and cooling demand by 50% in comparison to average energy demand. • passive solar energy. Good building design can make use of solar energy design, through orientation of the building’s site and windows. the term “passive” indicates that no mechanical equipment is used, because solar gains are brought in through windows and shading keeps the heat out in summer. • balanced ventilation with heat recovery. heated indoor air passes to a heat recovery unit and is used to heat incoming outdoor air.

figure 11.15 | elements of new building design that can substantially reduce energy use primary energy use per capita

11 4

6 5

5 7

1. heat pump systems that utilise the stable temperature in the Ground to support air conditioninG in summer and heatinG or hot Water supply in Winter. 2. trees to provide shade and coolinG in summer, and shield aGainst cold Wind in Winter. 3. new battery technology for the storaGe of the electricity produced by solar panels. 4. transparent design to reduce the need for liGhtinG. “low-e” glass coating to reduce the amount of heat absorbed from sunliGht throuGh the WindoWs (WindoWs With the reverse effect can be installed in colder climates). source Wbcsd, 2005.

references 12

Wbcsd (World business council on sustainable development) (2005). pathWays to 2050 – enerGy and climate chanGe. iea (2006). enerGy technoloGy perspectives – scenarios and strateGies to 2050. oecd/iea, 2006.

280

5. efficient liGht bulbs. 6. solar photovoltaic panels for electricity production and solar thermal panels for Water heatinG. 7. rooms that are not normally heated (e.G. a GaraGe) servinG as additional insulation. 8. ventilated double skin façades to reduce heatinG and coolinG reQuirements. 9. wood as a buildinG material With advantaGeous insulation properties, Which also stores carbon and is often produced With biomass enerGy.

energy

[r]evolution

for existing buildings, retrofits help reduce energy use. important retrofit options are more efficient windows and insulation, which can save 39% and 32% of space heating or cooling demand, respectively, according to the international energy agency (iea 2006). furthermore, the iea reports that average energy consumption in current buildings in europe can decrease overall by more than 50%. in 2015, the iea reconfirmed that energy use by space heating, cooling and lighting, which represents 38% of global buildings energy consumption, could be reduced by more than half by ensuring that building envelopes are energy efficient (iea etp 2015). While the technologies are there, the political process is far too slow to exploit these large cost effective efficiency potentials. to improve the efficiency of existing heating systems, an option is to install new thermostatic valves, which can save 15% of energy required for heating. on average, this option is installed in an estimated 40% of systems in europe. 13 effective air sealing can reduce heating and cooling energy by 20% to 30% and needs to be implemented as part of any construction and renovation project. more effort is needed globally to ensure that any building that will be heated or cooled is properly sealed. When sealing is done correctly, with controlled ventilation and advanced heat recovery, it can improve indoor air quality (iea etp 2015). besides reducing the demand for heating, another option is to improve the conversion of efficiency of heat supply. a number of options are available, such as high efficiency boilers that can achieve efficiencies of 107%, based on lower heating value. another option is the use of heat pumps. hot water and cooking

energy savings options for hot water include pipe insulation and high efficiency boilers. another option is heat recovery units that capture the waste heat from water going down the drain and use it to preheat cold water before it enters the household water heater. a heat recovery system can recover as much as 70% of this heat and recycle it back for immediate use. 14 furthermore, water-saving shower heads and flow inhibitors can be implemented. the typical saving rate (in terms of energy) for shower heads is 12.5% and 25% for flow inhibitors. 15 in developing regions, improved cook stoves can be an important energy-efficiency option, which consume less energy than conventional ones. 16

electricity use

electricity savings options per application are discussed in the following. electricity for space heating and hot water

measures to reduce electricity use for space heating and hot water are similar to measures for heating by fuels. changing the building shell can reduce the need for heat, and the other approach is to improve the conversion efficiency of heat supply, for example with heat pumps to provide both cooling and space and water heating, as discussed in chapter 10 (renewable heating and cooling technologies). typically, heat pumps can produce from 2.5 to 4 times as much useful heat as the amount of high-grade energy input, with variations due to seasonal performance. the sales of heat pumps in a number of major european markets experienced strong growth in recent years. total annual sales in austria, finland, france, Germany, italy, norway, sweden and switzerland reached 636,000 in 2013, compared to 446,000 in 2005. 17 data suggests that heat pumps may be beginning to achieve a critical mass for space and water heating in a number of european countries.

lighting

incandescent bulbs have been the most common lamps for a more than 100 years but also the most inefficient type since up to 95% of the electricity is lost as heat. 18 incandescent lamps have a relatively short life-span (average approximately 1,000 hours) but have a low initial cost and attractive light colour. compact fluorescent light bulbs (cfls) are more expensive than incandescent, but they use about a quarter of the energy and last about 10 times longer. 19 in recent years, many policies have been implemented that reduce or ban the use of incandescent light bulbs in various countries. however, energy savings from lighting are not just a question of using more efficient lamps but also involve other approaches: reducing light absorption of luminaries (the fixture in which the lamp is housed), optimizing lighting levels (which commonly exceed values recommended by iea (2006)), using automatic controls like movement and daylight sensors, and retrofitting buildings to make better use of daylight. buildings designed to optimize daylight can receive up to 70% of their annual illumination needs from daylight, while a typical building will only get 20 to 25%. the light-emitting diode (led) is one of today’s most energyefficient and rapidly-developing lighting technologies. led is a highly energy efficient lighting technology and has the potential to fundamentally change the future of lighting. residential leds use at least 75% less energy, and last 25 times longer than incandescent lighting. 20

references 13

14 15

bettGenhäuser, k., t. boermans and s. schimschar (2009) sectoral emission reduction potentials and economic costs for climate chanGe (serpec-cc). residential buildinGs and service sector. ecofys, netherlands. enviroharvest (2008) heat recovery. http://WWW.enviroharvest.ca/heat_recovery.htm bettGenhäuser, k., t. boermans and s. schimschar (2009) sectoral emission reduction potentials and economic costs for climate chanGe (serpec-cc). residential buildinGs and service sector. ecofys, netherlands.

16 17 18 19 20

reeep (2009) implementation of a dissemination strateGy for efficient cook stoves in northeast braZil. (ehpa 2014) european heat pump market and statistics report – european heat pump association. hendel-blackford, s., t. anGelini, s. oZaWa (2007) enerGy efficiency in life-styles: europe and japan. ecofys for eu-japan centre for industrial cooperation. enerGy star (2008) compact fluorescent liGht bulbs. http://WWW.enerGystar.Gov/index.cfm?c=cfls.pr_cfls (usa-enerGy-Gov 2014) enerGy.Gov Website (http://enerGy.Gov/enerGysaver/articles/led-liGhtinG), u.s. department of enerGy, 1000 independence ave. sW WashinGton dc 20585 / usa; november 2014.

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ict and home entertainment equipment

air conditioning

information and communication technologies (ict) and home entertainment consist of a growing number of appliances in both residential and commercial buildings, such as computers, (smart) phones, televisions, set-top boxes, games consoles, printers, copiers and servers. ict and consumer electronics account for about 15% of residential electricity consumption now. 21 Globally, a tripling is expected for ict and consumer electronics from 776 tWh/a in 2010 to 1,700 tWh/a in 2030. one of the main options for reducing energy use in ict and home entertainment is using best available technology. iea (2009b) estimates that a reduction is possible from 1,700 tWh/a to 775 tWh/a in 2030 by applying best available technology and to 1,220 tWh/a by least life-cycle costs measures, which do not impose additional costs on consumers. below, we discuss other energy savings options for ict and home entertainment.

there are several options for technological savings from air conditioning equipment; one is using a different refrigerant. tests with the refrigerant ikon b show possible energy consumption reductions of 20-25% compared to refrigerants commonly used. 24

other appliances

solar energy can also be used for heating and cooling; the different types are also discussed in chapter 10 renewable heating and cooling. heat pumps and air conditioners that can be powered by solar photovoltaic systems, 25 for example, use only 0.05 kW electric power instead of 0.35 kW for regular air conditioning. 26 in addition to efficient air conditioning equipment, it is as important to reduce the need for air conditioning. insulation can be used to prevent heat from entering the building along with fewer inefficient appliances in the house (such as incandescent lamps, old refrigerators, etc.) that give off heat, cool exterior finishes (such as cool roof technology 27 and light-coloured paint on the walls) to reduce the peak cooling demand as much as 10-15% 28, better windows, vegetation to reduce the amount of heat that comes into the house, and ventilation instead of air conditioning units.

figure 11.16 | global final energy use in the period 2012-2050 in industry in the energy [r]evolution and the reference demand scenario distinguished by electricity and fuels/heat 140,000 120,000 100,000 80,000 PJ/a

other appliances include cold appliances (freezers and refrigerators), washing machines, dryers, dish washers, ovens and other kitchen equipment. electricity use for cold appliances depends on average per household storage capacities, the ratio of frozen to fresh food storage capacity, ambient temperatures and humidity, and food storage temperatures and control (iea, 2003). european and japanese households typically have one combined refrigerator-freezer in the kitchen or they have a refrigerator and a separate freezer. in oecd north america and australia, where homes are larger, almost all households have a refrigerator-freezer, and many also have a separate freezer and occasionally a second refrigerator. 22 it is estimated that by improving the energy efficiency of cold appliances, on average 45% of electricity use could be saved for eu-27. 23 for â&#x20AC;&#x153;wet appliances,â&#x20AC;? an estimated potential of 40-60% could be saved by implementing best practice technology.

Geothermal cooling is another important option explained in chapter 10. of several technical concepts available, the highest energy savings can be achieved with two storage reservoirs in aquifers where cold water is used from the cold reservoir in summer. the hot reservoir can be used with a heat pump for heating in winter.

60,000 40,000

references 21 22 23 24

25 26

27 28

iea (2009b) GadGets and GiGaWatts. international enerGy aGency. paris, france. iea (2003) cool appliances - policy strateGies for enerGy efficient homes. https://WWW.iea.orG/textbase/nppdf/free/2000/cool_appliance2003.pdf bettGenhauser et al. (2009). us doe eere (united states department of enerGy; enerGy efficiency and reneWable enerGy) (2008) inventions & innovation project fact sheet. hiGh enerGy efficiency air conditioninG. http://WWW1.eere.enerGy.Gov/inventions/pdfs/nimitZ.pdf darlinG, d. (2005) solar coolinG. the encyclopedia of alternative enerGy and sustainable livinG. http://WWW.daviddarlinG.info/encyclopedia/s/ae_solar_coolinG.html austrian enerGy aGency, 2006 - note that solar coolinG and Geothermal coolinG may reduce the need for hiGh Grade enerGy such as natural Gas and electricity. on the other hand they increase the use of reneWable enerGy. the enerGy savinGs achieved by reducinG the need of hiGh Grade enerGy Will be partly compensated by an increase of reneWable enerGy. us epa (united states environmental protection aGency) (2007) cool roofs. http://WWW.epa.Gov/heatisld/strateGies/coolroofs.html aceee (american council for an enerGy-efficient economy) (2007) consumer Guide to home enerGy savinGs - coolinG eQuipment. http://WWW.aceee.orG/consumerGuide/coolinG.htm#reduce

282

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- FUELS - E[R]

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- ELECTRICTY - E[R]

source iea Weo 2014 / dlr calculations for reference and e[r] case (2015).

energy

[r]evolution

11.5 efficiency [r]evolution

pathways

the

energy figure 11.18 | global final energy use in the period 2012-2050 in other sectors in the energy [r]evolution and the reference scenario distinguished by electricity and fuels/heat

11.5.1 low demand scenario for industry sector

figure 11.16 shows the resulting energy demand scenarios for the sector industry on a global level. energy demand in electricity can be reduced by 23% and nearly 60% for fuel use, in comparison to the reference scenario in 2050. in comparison to 2012, global fuel use in industry decreases from 78 ej to 50 ej and electricity use shows an increase from 29 ej to 48 ej which is also a result of the substitution of fuel use for heating with electric heating systems.

140,000 120,000 100,000

PJ/a

80,000

figure 11.17 shows the final energy demand in the industrial sector per region for total energy demand. large reductions are assumed in all regions, especially in the developing countries.

60,000 40,000 20,000

11.5.2 low demand scenario for buildings and other sectors

figure 11.18 shows the resulting energy demand scenarios for the buildings and agriculture sector on a global level. energy demand for electricity is reduced by 33% and for fuel by 46%, in comparison to the reference scenario in 2050. in comparison to 2012, global fuel use in this sector decreases from 92 ej to 62 ej while electricity use shows a strong increase from 38 ej to 58 ej.

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- ELECTRICTY - E[R]

source iea Weo 2014 / dlr calculations for reference and e[r] case (2015).

figure 11.17 | final energy use in sector industry in the energy [r]evolution and the reference demand scenario distinguished by world regions 60,000

50,000

PJ/a

40,000

30,000

20,000

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10,000

2050 REFERENCE 2050 ENERGY [R]EVOLUTION AFRICA

MIDDLE EAST

LATIN AMERICA

OTHER ASIA

CHINA

INDIA

EASTER EUROPE/EURASIA

OECD EUROPE

OECD ASIA OCEANIA

OECD NORTH AMERICA

source iea Weo 2014 / dlr calculations for reference and e[r] case (2015).

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decreases strongly due to the implementation of ambitious efficiency measures for heating in the energy [r]evolution. the resulting energy intensities for different world regions show a convergence until 2050 but still large differences between developed and developing countries which are a result of the economic and population growth assumptions, assumed developments in the reference scenario according to Weo 2014 and the assumption that available efficiency potentials are implemented in all world regions. different assumptions for economic growth and their consequences for lifestyle are possible especially for africa, india and other asia and may lead to significant higher demand pathways and therefore higher infrastructural needs for a secure energy supply. further research is needed here in order to take into account different societal and economic pathways and how these could affect energy demand in different world regions. on the other side an even larger deployment of potentials for renewable energies is possible in most regions and can ensure that requirements for an additional energy supply can be met.

figure 11.19 shows the final energy demand in the buildings and agriculture (= other sectors) per region for total final energy demand. decreases in absolute terms are strongest in the oecd regions while in most developing countries population will further grow and the use of electronic and other devices will further proliferate. 11.6 development of energy intensities resulting specific energy consumption in transport, industry and other sectors are shown in figure 11.20 to figure 11.22 in terms of global averages and in figure 11.23 for each world region as total final energy demand of all sectors. energy intensity in transport and industry decreases significantly already in the reference scenario while in the energy [r]evolution scenario an even stronger decoupling of economic growth and energy consumption is assumed. specific electricity demand in other sectors increases only slightly from 5.6 to 6.1 Gj per capita (1,550 kWh/capita to 1,690 kWh/capita) while specific fuel demand

figure 11.19 | final energy use in other sectors in the energy [r]evolution and the reference scenario distinguished by world regions 35,000 30,000 25,000

PJ/a

20,000 15,000 10,000

2012

5,000

2050 REFERENCE 2050 ENERGY [R]EVOLUTION

source iea Weo 2014 / dlr calculations for reference and e[r] case (2015).

284

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LATIN AMERICA

OTHER ASIA

CHINA

INDIA

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OECD EUROPE

OECD ASIA OCEANIA

OECD NORTH AMERICA

energy

[r]evolution

figure 11.20 | average global energy intensities in transport – final energy per $ gdp in the energy [r]evolution and the reference scenario

figure 11.22 | average global energy intensities in other sectors – electricity and fuels/heat demand per capita in the energy [r]evolution and the reference scenario

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- REFERENCE

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- ENERGY [R]EVOLUTION

FUELS/HEAT

- REFERENCE

FUELS/HEAT

- ENERGY [R]EVOLUTION

FINAL ENERGY

- ADVANCED ENERGY [R]EVOLUTION

ELECTRICITY

- REFERENCE

ELECTRICITY

- ENERGY [R]EVOLUTION

source iea Weo 2014 / dlr calculations for reference and e[r] case (2015).

figure 11.21 | average global energy intensities in industry – electricity and fuels/heat demand per $ gdp in the energy [r]evolution and the reference scenario

figure 11.23 | average global energy intensities per world region – final energy per capita in the energy [r]evolution scenario

800

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source iea Weo 2014 / dlr calculations for reference and e[r] case (2015).

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- ENERGY [R]EVOLUTION

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LATIN AMERICA

OECD EUROPE

source iea Weo 2014 / dlr calculations for reference and e[r] case (2015).

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OECD ASIA OCEANIA

CHINA

OECD NORTH AMERICA

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2050

source iea Weo 2014 / dlr calculations for reference and e[r] case (2015).

285

transport the future of the transport sector in the reference scenario

technical and behavioural measures to reduce transport energy consumption

projection of the future car market

conclusion

12 “

the transport revolution must start in megacities.”

image late spring and summer weather brings blooms of color to the atlantic ocean off of south america, at least from a satellite view. the patagonian shelf break is a biologically rich patch of ocean where airborne dust from the land, iron-rich currents from the south, and upwelling currents from the depths provide a bounty of nutrients for the grass of the sea—phytoplankton. in turn, those floating sunlight harvesters become food for some of the richest fisheries in the world.

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sustainable transport is needed to reduce the level of greenhouse gases in the atmosphere, just as much as a shift to renewable electricity and heat production. today, the transport sector requires just over one fourth (27%) (iea Weo sr 2015) 1 of current energy use, including road and rail, aviation and sea transport. by the end of 2013, 92.7% of all transport energy demand was provided by oil products, 2.5% from bio fuels and only 1% from electricity (iea Weo sr 2015). a transition from fossil fuels to renewable electricity – either directly or via synthetic fuels – for the entire global transport sector is required in order to phase-out carbon emissions. this is one of the most difficult parts of the energy [r]evolution and requires a true technical revolution. it is ambitious but nevertheless possible with currently available technologies for land-based and other transport. 14% of all fossil transport fuels are used for “bunker fuel,” meaning transport energy for international shipping and international air transport. in order to replace bunker fuels entirely with renewables, a combination of energy efficiency and renewable fuels is required. both the marine and aviation sector can start this transition, but we need more research and development along the way towards a truly 100% renewable system. biofuels and synthetic hydrocarbons (synfuels) – produced with renewable electricity – are the only realistic renewable energy option for planes currently and for the next decade. for ships, new wind-based drives, such as new generation sails and flettner rotors, are needed to replace a proportion of engine fuels. the transport [r]evolution however must start in (mega)cities where a modular shift from individual to efficient and convenient public transport systems powered by renewable electricity is possible in a short time frame and with currently available technologies. political action is the main barrier in changing land-based transport systems. in order to assess the present status and potential technological pathways of global transport, including its carbon footprint, a special study about technical efficiency potentials and the effect of modular shifts in the transport sector was undertaken for the 2012 energy [r]evolution report by the German aerospace center’s (dlr) institute of vehicle concepts (dlr 2012) 2 analyzing the entire global transport sector based on the ten iea world regions. the institute carried out new technical research for Greenpeace in early 2015, focusing on the latest developments of landbased transport systems, especially for megacities (dlr 2015). 3 the resulting key parameters of this study are shown in table 12.7.

the demand projections for both energy [r]evolution scenarios are based on the afore-mentioned research work. the scenario base year has been updated using the 2014 iea energy balances. the projections of the transport sector in the reference scenario are based on iea Weo 2014. assumed parameters for person and freight kilometres, occupancy rates and vehicle market development have not been re-calculated but adapted to the new base year 2012 as opposed to 2009 in the previous report. the advanced energy [r]evolution scenario starts with the same technical and modal shift pathways but introduces them more quickly and to a larger extent. in addition, the advanced scenario replaces almost the entire remaining fossil fuel demand with synfuels, hydrogen and renewable methane produced from renewables from 2035 onwards. thus, the electricity demand in the advanced energy [r]evolution is significantly higher. this chapter provides an overview of selected measures appropriate to develop a more energy efficient and sustainable transport system in the future, with a focus on: • reducing transport demand, • shifting transport ‘modes’ (from high to low energy intensity), and • improving energy efficiency from technology development. the section provides plausible transport energy demand calculations including projections for the passenger vehicle market (light duty vehicles) used as background knowledge for the updated energy [r]evolution transport pathways. overall, some technologies will have to be adapted for greater energy efficiency. in other situations, a simple modification will not be enough. the transport of people in megacities and urban areas will have to be reorganised almost entirely and individual transport must be complemented or even substituted by public transport systems. car sharing and public transport on demand are only the beginning of the transition needed for a system that carries more people more quickly and conveniently to their destination while using less energy.

references 1 2 3

(iea-Weo sr 2015); World enerGy outlook – special report 2015, international enerGy aGency; june 2015. (dlr 2012); project report – transport scenario buildinG in the e[r] 2012. paGenkopf, j., schmid, s., frieske, b., German aerospace center (dlr), institute of vehicle concepts; stuttGart, Germany. (dlr 2015); project report - alternative transport technoloGies for meGacities; German aerospace center (dlr), institute of vehicle concepts; stuttGart, Germany.

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12.1 the future of the transport sector in the reference scenario as for electricity projections, a detailed reference scenario is required for transport. the scenario constructed includes detailed market shares and energy intensity data per mode of transport and per region up to 2050 (sources: Wbscd, eu studies). based on the reference scenario, deviating transport performance and technical parameters are applied to create both energy[r]evolution scenarios for reducing energy consumption. traffic performance is assumed to decline for the high energy intensity modes and further energy reduction potentials were assumed from further efficiency gains, alternative power trains and fuels. the advanced energy [r]evolution introduces electric mobility faster and replaces all remaining fossil fuels between 2040 and 2050 with renewable synfuels, especially in the marine and aviation transport sectors.

the total transport energy demand is made up of light duty vehicles (ldvs), heavy and medium duty freight trucks, rail, air, and national marine transport (inland navigation). although energy use from international marine bunkers (international shipping fuel suppliers) is not included in these calculations, it is still estimated to account for 14% of today’s worldwide transport final energy demand and around 15% by 2050 in the reference scenario. a un report concluded that carbon dioxide emissions from shipping are much greater than initially thought and increasing at an alarming rate (eyring et al 2005). 4 it is therefore very important to improve the energy efficiency of international shipping. possible options are examined later in this chapter. the definitions of the transport modes for the scenarios are: (fulton 2004) 5

• light duty vehicles (ldv) are four-wheel vehicles used primarily for personal passenger road travel. these are typically cars, sports utility vehicles (suvs), small passenger vans (up to eight seats) and personal pickup trucks. light duty vehicles are also simply called ‘cars’ within this chapter. • heavy duty vehicles (hdv) are long-haul trucks operating almost exclusively on diesel fuel. these trucks carry large loads with lower energy intensity (energy use per tonnekilometre of haulage) than medium duty vehicles, such as delivery trucks. • medium duty vehicles (mdv) include medium-haul trucks and delivery vehicles. • aviation in each region denotes domestic air travel (intraregional and international air travel is provided as one figure). • inland navigation denotes freight shipping with vessels operating on rivers and canals or in coastal areas for domestic transport purposes figure 12.1 shows the breakdown of worldwide final energy demand for the transport modes in 2012 and 2050 in the reference scenario. the largest share of energy demand comes from ldv (mainly for passenger road transport), although it decreases from 71% in 2012 to 68% in 2050. the share of domestic air transport increases from 4.6% to 5.1%. of particular note is the high share of road transport in total transport energy demand: 87% in 2012 and 82% in 2050. overall energy demand in the transport sector adds up to 90 ej in 2012. it is projected in the reference scenario to increase to 150 ej in 2050.

figure 12.1 | world final energy use per transport mode 2012 – 2050 – reference scenario 2012

2050 AVIATION, 5% NAVIGATION, 2% RAIL, 3%

AVIATION, 5% NAVIGATION, 2% RAIL, 3%

ROAD,

90%

references 4 5

(eyrinG et al 2005) eyrinG, v., köhler, h., lauer, a., lemper, b. (2005): emissions from international shippinG: 2. impact of future technoloGies on scenarios until 2050, journal of Geophysical research, 110, d17305. (fulton 2004); fulton, l. and eads, G. (2004): iea/smp model documentation and reference case projection, published by Wbscd.

288

90%

energy

[r]evolution

in the advanced energy [r]evolution scenario, implying the implementation of all efficiency and behavioural measures described, we calculated in fact a decrease of energy demand to 70 ej, which means a lower annual energy consumption than in 2012.

half of the total amount by oecd north america and oecd europe. in 2050, the picture looks more fragmented. in particular, china and india form a much bigger portion of the world transport energy demand, whereas oecd north america remains the largest energy consumer.

figure 12.2 shows world final energy use for the transport sector per region in 2012 and 2050 in the reference scenario. today, energy consumption is comprised by nearly

12.2 technical and behavioural measures to reduce transport energy consumption

table 12.1 | selection of measures and indicators measure

reduction option

reduction of transport demand

indicator

reduction in volume of passenGer

passenGer-km/capita

transport in comparison to the reference scenario reduction in volume of freiGht

tonnne-km/

transport in comparison to the

unit of Gdp

reference scenario modal shift

modal shift from trucks to rail

mj/tonne-km

modal shift from cars to

mj/passenGer-km

the following section first describes how the transport modes contribute to total and relative energy demand. next, selections of measures for reducing total and specific energy transport consumption are put forward for each mode. measures are grouped as either behavioural or technical. the three ways to decrease energy demand in the transport sector examined are: • reduction of transport demand of high energy intensity modes • modal shift from high energy intensive transport to low energy intensity modes • energy efficiency improvements.

public transport enerGy efficiency improvements

shift to enerGy efficient passenGer

mj/passenGer-km,|

car drive trains (battery electric

mj/tonne-km

vehicles, hybrid and fuel cell hydroGen cars) and trucks (fuel cell hydroGen, battery electric, catenary or inductive supplied) shift to poWertrain modes that may

mj/passenGer-km,

be fuelled by reneWable enerGy

mj/tonne-km

(electric,

fuel cell hydroGen)

autonomous efficiency

mj/passenGer-km,

improvements of ldv, hdv, trains,

mj/tonne-km

airplanes over time

12.2.1 behavioural measures to reduce transport energy demand

understanding people and behaviour is the key. sustainability is about our lifestyle choices. it is about how people live their daily lives and, as humans, how we base our decisions on our surrounding environment. most people make decisions based on what is convenient and inviting. the energy [r]evolution transport pathways do not rely on the very few idealists who always do ‘the right thing’. therefore, cities in particular have to change so that making the ‘right choice’ will be also the ‘easiest choice.’

figure 12.2 | world final energy use by region 2012 – 2050 – reference scenario 2012

2050

OECD ASIA

OCEANIA, CHINA,

20%

OECD ASIA

OECD NORTH AMERICA,

LATIN AMERICA, OTHER ASIA, INDIA,

6% MIDDLE EAST, 5%

OECD EUROPE,

21%

CHINA,

21%

6% OTHER ASIA,

14%

EASTERN EUROPE/EURASIA, AFRICA,

OCEANIA,

INDIA,

11% MIDDLE EAST, 7%

OECD NORTH AMERICA, LATIN AMERICA,

OECD EUROPE,

10%

15%

EASTERN EUROPE/EURASIA, AFRICA,

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greenpeace promotes sustainable mobility via three different approaches:

1. avoid: avoid transport where it is not necessary by embracing the ‘compact city’ model. 2. shift: encourage the use of more sustainable transport (such as public transport, walking, cycling) and discourage usage of private motorized transport. 3. improve: the least efficient modes of transport (such as private cars) have to become as efficient as possible. the point of departure for an urban mobility strategic concept that promotes sustainable mobility is the quality of the public realm, with its streets and spaces that stimulate sustainable mobility choices to contribute to quality of life – safe, economical, sustainable, inclusive (Greenpeace Germany 2015): 6 • reduction of car dependency • sustainable transportation modes • more efficient land use by density • mixed-use development that form mixed-modal urban hubs that are easily accessible destination points.

technical measures – urban electric mobility

currently, to achieve a locally emission-free land transport option, electric motors are utilized as the main powertrain. the electricity may be provided to the electric motor via several means either on or off-board:

• battery electric powertrain: the electricity is generated offboard and stored on-board via electro-chemical energy storage units, • catenary electric powertrain: the electricity is generated off-board and constantly supplied to the vehicle via an external catenary during driving, • fuel cell electric powertrain: the electricity is generated onboard with a fuel cell via reaction of hydrogen and oxygen battery electric powertrain

a battery electric vehicle (bev) utilizes an electric motor to convert electrical energy into mechanical energy and requires a battery for the energy storage. the battery is connected to electric motor via a dc/ac converter including a control system (Grunditz, 2014).7 most of the bevs have a gearbox with only one gear ratio (lienkamp, 2014).8 if the vehicle has only one central electric motor, then a differential is needed similar to those in conventional vehicles. the structure of a bev with a central electric motor is presented schematically in figure 12.3. the battery is considered to be one of the most critical components of electrified vehicles due to its cost-intensive nature. furthermore, batteries have lower energy density resulting in limited driving ranges combined with high volumes and masses of the energy storage system. therefore, batteries (especially lithium-based ones) have been subject to tremendous research efforts in recent years and this trend is expected to continue in the following years (Wagner, preschitschek et al., 2013) 9 with improvements in costs, life expectancy and energy density.

figure 12.3 | schematic architecture of battery electric vehicles (bev)

7 8

5 6

CHARGING UNIT

ELECTRIC CONNECTION

BATTERY SYSTEM

ELECTRIC MACHINE

AUXILIARIES

MECHANICAL CONNECTION

POWER ELECTRONIC

GEARBOX INCLUDING FINAL DRIVE

source dlr.

references 6 7

(Greenpeace Germany 2015): Greenpeace strateGy for Green mobility; d. moser /Gpd; Gehl architects denmark 2015. GrunditZ, e. a. (2014). bev poWertrain component siZinG With respect to performance, enerGy consumption and drivinG patterns. department of enerGy and environment, chalmers university of technoloGy licentiate of enGineerinG.

290

8 9

lienkamp, m. (2014). status of electrical mobility 2014 WaGner, r., n. preschitschek, et al. (2013). “current research trends and prospects amonG the various materials and desiGns used in lithium-based batteries.” j appl electrochem 43: 481-496.

energy

[r]evolution

several quick battery charging strategies for battery electric road and rail vehicles beyond common conductive cablebased charging have emerged in recent years (some of which have already entered commercialization): • conductive quick charging: this strategy is mainly designed for buses and trams. the charging at high power rates (200500 kW) is performed at intermediate and turning points via extendable pantographs; a demonstration project for buses is, for example, in day-to-day use in Geneva, switzerland (sae off-highway engineering online, 2013). 10 • inductive quick charging:

◦ several research and demonstration projects on inductive charging at traffic lights or even dynamically inroad-charging exist for passenger cars (eGvi, 2014; Wich, 2014). 11

◦ for buses at intermediate stops and 10-30 minutes recharging at turning points, several research, demonstration and commercialization projects are underway operating with a charging power of 50-200 kW (fta, 2014b). 12 • battery swapping stations

◦ china has used robotic battery swapping stations for its urban battery electric buses in several cities since 2008 (li, 2013). 13

◦ battery car maker tesla has installed a commercial battery swap station in california allowing a battery swap in about 3 minutes (forbes, 2014). 14

• both inductive charging at stations and battery swap stations demand high infrastructural investments but enable a reduction of on-board battery capacity, weight, and hence vehicle cost (and allowing also an increase of passenger load). although battery-electric drivetrains could also be applied to rail applications, only road battery electric vehicles are considered in this study since external catenary systems are best suited to rail-bound urban mass rapid transit systems. the advantages of battery electric road vehicles compared to conventional internal combustion engine vehicles are summarized below:

• lower variable costs (mainly fuel) • higher torque compared to internal combustion engine at low speed • lower vibrations and noise however, battery electric road vehicles have also some drawbacks compared to internal combustion engine vehicles, which include: : • limited driving range due to lower energy density • longer charging time, • additional infrastructure requirement for charging points • higher purchase costs (at the moment) catenary electric powertrain

public transport systems, such as trams (light rail trains), metro, commuter train and trolley bus systems are operated on rail or road networks equipped with electric overhead wires or third rails alongside the track. the electric power is continuously transferred to the vehicle via the wire or third rail, usually direct current (dc) with 500 – 1500 v, and drawn by a current collector installed on the vehicle. sometimes, also alternate current (ac) systems with higher voltages are applied in commuter rail systems. urban tram, metro and usually also commuter rail systems draw the electricity from an overhead catenary or a third rail. road trolley buses operate with special current collectors under two overhead wires; one is to draw the current from the wire and the other to close the circuit. in recent years, overhead catenary trucks for goods transport on roads have been in discussion (den boer, aarnik et al., 2013) 15, but no such system has begun to enter commercial service in an urban environment up to now. furthermore, overhead catenary trucks are not expected to be in service in the megacities in the near future (about 5 years). in general, overhead catenary systems can be distinguished by transport application as presented in table 12.2.

table 12.2 | overhead catenary and third rail systems in urban public transport applications

• Zero local emissions • significant lower well-to-wheel greenhouse gas emissions possible (depending on the electricity generation)

transport applications

energy supply system

tram/liGht rail metro

typical voltage levels

500-750 v dc overhead catenary

750-1500 v dc

references 10 11 12 13 14

sae off-hiGhWay enGineerinG online (2013). “abb ‘flash charGes’ electric bus in 15 s.” retrieved 20.01.2015, from http://articles.sae.orG/12293/. eGvi (2014). “unpluGGed - inductive charGinG for electric vehicles (february 2014).” retrieved 28.01.2015, from http://WWW.eGvi.eu/projects/13/38/unpluGGed-inductive-charGinG-for-electric-vehicles-february-2014. fta (2014b). revieW and evaluation of Wireless poWer transfer (Wpt) for electric transit applications, fta report no. 0060, federal transit administration. f. t. a. u.s. department of transportation. li, j. l. f. (2013). “case study of ev city bus operations.” from http://bestar.lbl.Gov/us-china-Workshop2013/files/2013/04/jan-li-lithium-force.pdf. forbes (2014). “tesla’s battery sWap stations Will help it reQualify for Zev credits in california.” retrieved 20.01.2015, from http://WWW.forbes.com/sites/Greatspeculations/2014/12/30/teslas-batterysWap-stations-Will-help-it-reQualify-for-Zev-credits-in-california/. den boer, e., s. aarnik, et al. (2013). Zero emissions trucks - an overvieW of state-of-the-art technoloGies and their potential. delft, ce delft.

0.75-1.5 kv dc

commuter train metro, commuter train trolley bus

15/25 kv ac

third rail

750-1500 v dc

overhead catenary (tWo poles)

v dc

source dlr vehicle database.

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vehicles drawing traction electricity continuously from a catenary are advantageous over battery electric and fuel cell vehicles in terms of the following aspects: • the traction energy is continuously drawn from an external current wire making expensive and heavy vehicle on-board storage systems unnecessary, • there is no need to refuel (as with fuel cell hydrogen vehicles) or to recharge (as with battery electric vehicles) and, thus, the operating range, within network borders, is not limited, • high vehicle efficiency levels (80-90 %), • proven and well-known system on infrastructure and vehicle level for decades, • especially useful for highly frequented public transport networks. in certain cases, however, overhead electrification may not prove advantageous over battery electric and fuel cell vehicles. some drawbacks of catenary electrification include: • visual intrusion through overhead wire network, undesired especially in historically valuable city areas,

• high capital expenditure for wayside energy infrastructure that may not pay off in case of low line-capacity utilization, • vehicles are bound to the fixed catenary network, • application restricted to public transport systems – the system is not useable for passenger cars.

fuel cell electric powertrain

in contrary to the vehicle using batteries or overhead lines, fuel cell- and hybrid electric vehicles provide traction power by using a fuel cell as energy converter of chemical energy (mostly hydrogen) into electrical energy based on ionic catalytic breakdown of the molecular fuel at the anode. figure 11.4 illustrates an exemplary fuel cell powertrain with a central electric motor. key elements of this system are the hydrogen storage and fuel cell system. there are several ways to store hydrogen on board, such as in liquid form, compressed under high pressure, or via physical and chemical compounds (eichlseder and klell, 2012). 16 the state of the art is compressed hydrogen storage under 350 and 700 bar using composite materials for the tanks, which prevents hydrogen diffusion and ensures safety. the 700 bar technology allows for a higher energy storage capacity than 350 bar storage. energy losses due to compression amounts to approximately 15 % of the energy content of hydrogen, significantly less than hydrogen stored in liquid form (30-40 % losses) (ferrari, offinger et al., 2012). 17 there are several fuel cell types. in cars, pem fuel cells are used. the reactants here are hydrogen (h 2) at the anode and oxygen (o 2) at the cathode. the only waste product of the reaction is water. although fuel cell electric vehicles (fcevs) could also be used for rail applications, only road vehicles are considered in this study. the advantages of fuel cell electric road vehicles are summarized below:

figure 12.4 | schematic architecture of fuel cell electric vehicles (fcev)

8 9

6 7

1 2

source dlr.

references 16 17

eichlseder, h. and m. klell (2012). Wasserstoff in der fahrZeuGtechnik, sprinGer. ferrari, c., s. offinGer, et al. (2012). studie Zu ranGe extender konZepten für den einsatZ in einem batterieelektrischen fahrZeuG - rexel. stuttGart, dlr-fk.

292

HYDROGEN STORAGE

ELECTRIC CONNECTION

FUEL CELL SYSTEM

ELECTRIC MACHINE

AUXILIARIES

MECHANICAL CONNECTION

POWER ELECTRONIC

GEARBOX INCLUDING FINAL DRIVE

BATTERY SYSTEM

energy

[r]evolution

• Zero local emissions • possibly lower well-to-wheel greenhouse gas emissions than internal combustion engine vehicles (depending on how the hydrogen is produced) • high efficiency of fuel cells compared to internal combustion engine, particularly at low temperatures • lower vibrations and noise than conventional vehicles • higher range of operation than bevs • significant shorter refueling times than recharging times for bevs

in the reference scenario, there is a forecast increase in passenger-km in all regions up to 2050. for the 2050 energy [r]evolution scenario, there is still a rise, but it would be much flatter. for oecd europe and oecd north america there will even be a decline in individual transport on a per capita basis. the reduction in passenger-km per capita in the advanced energy [r]evolution scenario compared to the reference scenario comes with a general reduction in car use due to behavioural and traffic policy changes and partly with a shift of transport to public modes.

however, fuel cell electric road vehicles have also some drawbacks, which include:

a shift from energy-intensive individual transport to lowenergy demand public transport goes align with an increase in low-energy public transport person-km.

• higher purchase costs (even higher than bevs)

freight transport:

• requirement to build a hydrogen infrastructure

• durability and long-term performance of fuel cell stack especially for transient operation

it is difficult to estimate a reduction in freight transport. neither energy [r]evolution scenario includes a model for reduced volume for required freight transport, but it is assumed that a modular shift from road to rail and/or to battery or fuel cell power transport vehicles takes place.

step 1: reduction of transport demand

step 2: changes in transport mode

to use less transport overall means reducing the amount of ‘passenger-km (p-km)’ travelled per capita and reducing freight transport demand. the amount of freight transport is to a large extent linked to Gdp development and therefore difficult to influence. however, improved logistics – for example, optimal load profiles for trucks and a shift to regionally produced goods – can reduce transport demand.

determining which vehicles and transport modes are the most efficient for each purpose requires an analysis of the transport mode technologies. then, the energy use and intensity of each type of transport is used to calculate energy savings resulting from a transport mode shift. the following information is required:

• high purity requirements and high cost of hydrogen as fuel

passenger transport:

• passenger transport: energy demand per passenger kilometer, measured in mj/p-km.

the study focussed on the change in passenger km per capita of high-energy intensity air transport and personal vehicles modes. passenger transport by light duty vehicles (ldv), for example, is energy-demanding both in absolute and relative terms. policy measures that enforce a reduction of passenger km travelled by individual transport modes are an effective means to reduce transport energy demand. policy measures for reducing passenger transport demand in general could include:

• freight transport: energy demand per kilometre of transported tonne of goods, measured in mj/tonne-km.

• charge and tax policies that increase transport costs for individual transport

passenger transport:

• price incentives for using public transport modes • installation or upgrading of public transport systems • incentives for working from home • stimulating the use of video conferencing in business • improved cycle paths in cities.

for this study, passenger transport includes light duty vehicles, passenger rail and air transport. freight transport includes medium duty vehicles, heavy duty vehicles, inland navigation, marine transport and freight rail. Wbcsd 2004 data was used in (dlr 2012) as baseline data and updated where more recent information was available.

travelling by rail is the most efficient – but car transport improves strongly. figure 12.5 shows the worldwide average specific energy consumption (energy intensity) by transport mode in the base year and in the energy [r]evolution scenario in 2050. this data differs for each region. there is a large difference in specific energy consumption among the transport modes. passenger transport by rail will consume 28% less energy in 2050 than car transport and 85% less than aviation on a per p-km basis, so shifting from road to rail can produce large energy savings.

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world energy [r]evolution a sustainable world energy outlook

the energy [r]evolution scenario assumes that a certain proportion of passenger-kilometer of domestic air traffic and intraregional air traffic (i. e., traffic among two countries of one iea region) is suitable to be substituted by high speed rail (hsr). for international aviation, there is obviously no substitution potential to other modes whatsoever. table 12.3 displays the relative model shifts used in the calculation for the energy [r]evolution scenarios. Where the shares are higher, cities are closer to each other, so a substitution by high speed trains is a more realistic option (i. e. distances of up to 800 â&#x20AC;&#x201C; 1,000 km, compared to countries where they are far apart).

figure 12.5 | world average (stock-weighted) passenger transport energy intensities for today and 205018 2.0

1.5

MJ/p-km

from figure 12.5, we can conclude that passengers will need to shift from cars and especially air transport to less energyintensive passenger rail transport in order to reduce transport energy demand.

1.0

0.5

LDV

freight transport:

similar to figure 12.5, which showed average specific energy consumption for passenger transport modes, figure 12.6 shows the respective energy consumption for various freight transport modes in 2009 and in energy [r]evolution scenarios 2050, the values are weighted according to stock and traffic performance. energy intensity for all modes of transport is expected to decrease by 2050. in absolute terms, road transport has the largest efficiency gains whereas transport on rail and on water remain the modes with the lowest relative energy demand per tonne-km. rail freight transport will consume 8090% less energy per tonne-km in 2050 than long haul hdv. this means that large energy savings can be made following a shift from road to rail.

table 12.3 | air traffic substitution potential of high speed rail (hsr) 17 region

intraregional

oecd europe

30 %

15 %

oecd north america

20 %

10 %

oecd asia oceania

20 %

10 %

latin america

30 %

10 %

other (non oecd) asia

20 %

10 %

eastern europe/eurasia

10 %

china

20 %

10 %

middle east

30 %

10 %

india

20 %

10 %

africa

20 %

10 %

294

- REFERENCE

figure 12.6 | world average (stock-weighted) freight transport energy intensities for today and 2050 17 5.0

4.0

relative substitution of air traffic to hsr in 2050 domestic

Domestic Aviation

2050 ENERGY [R]EVOLUTION

MJ/t-km

STATUS QUO

Passenger Railway

3.0

2.0

1.0

Railway

STATUS QUO

Inland Navigation

HDV

MDV

- REFERENCE

2050 ENERGY [R]EVOLUTION

references 18

accordinG to (dlr 2012) for the 2012 edition of enerGy [r]evolution â&#x20AC;&#x201C; the advanced enerGy [r]evolution introduces the same efficiency technoloGies faster.

energy

[r]evolution

figure 12.7 | development of tonne-km over time in the reference scenario 17

• air transport • passenger and freight trains • trucks

Tonne-km per year

3.5E+13

• inland navigation and marine transport

3.0e+13

• cars

2.5E+13

in general, an integral part of an energy reduction scheme is an increase in the load factor – both for freight and passenger transport. as the load factor increases, fewer vehicles need to be employed, so the energy intensity decreases when measured per passenger-km or tonne-km.

2.0E+12 1.5E+12 1.0E+12 0.5E+12 00E+00

2009

2020

2030

2040

2050

HEAVY DUTY VEHICLES MEDIUM DUTY VEHICLES RAIL FREIGHT INLAND NAVIGATION

modal shifts for transporting goods in the energy [r]evolution

in the energy [r]evolution scenarios, as much road freight as possible should be shifted from road freight transport to less energy intensive freight rail to gain maximum energy savings from modal shifts. since the use of ships largely depends on geography, a modal shift is not proposed for national ships but instead a shift towards freight rail. as the goods transported by medium duty vehicles are mainly going to regional destinations (and are therefore not suitable for the long distance nature of freight rail transport), no modal shift to rail is assumed for this transport type. for long-haul heavy duty vehicles transport, however, especially low value density, heavy goods that are transported on a long range are suitable for a modal shift to railways (tavasszy 2011). 19 step 3: technical efficiency improvements

energy efficiency improvements are the third important way of reducing transport energy demand. this section explains ways for improving energy efficiency up to 2050 for each type of transport, namely:

references 19 20 21 22

(tavassy 2011); tavassZy, l. and van meijeren, j. (2011): modal shift tarGet for freiGht transport above 300 km: an assessment, discussion paper, 17th acea saG meetinG. (nasa 2011) bradley, m. and droney, c. (2011): subsonic ultra Green aircraft research: phase i final report, issued by nasa. (akerman 2005) akerman, j. (2005): sustainable air transport - on track in 2050. transportation research part d, 10, 111-126. (icao 2008): committee on aviation environmental protection (caep), steerinG Group meetinG, fesG caep/8 traffic and fleet forecasts.

in aviation, there are already sophisticated efforts to optimise the load factor; however, for other modes such as road and rail freight transport there is still room for improvement. for freight transport, logistics and supply chain planning can improve load factors, while enhanced capacity utilisation will do so in passenger transport. air transport

a study conducted by nasa (nasa 2011) 20 shows that the energy use of new subsonic aircrafts can be reduced by up to 58% up to 2035. potentially, up to 81% reductions in co 2 emissions are achievable when using biofuels. (akerman 2005) 21 reports that a 65% reduction in fuel use is technically feasible by 2050. technologies to reduce fuel consumption of aircrafts mainly comprise: • aerodynamic adaptations to reduce the drag of the aircraft, for example by improved control of laminar flow, the use of riblets and multi-functional structures, the reduction in fasteners, flap fairings and the tail size as well as advanced supercritical airfoil technologies. • structural technologies to reduce the weight of the aircraft while at the same time increasing stiffness. examples include the use of new lightweight materials like advanced metals, composites and ceramics, the use of improved coatings, and the optimised design of multi-functional, integrated structures. • subsystem technologies, including advanced power management and generation along with optimised flight avionics and wiring. • propulsion technologies like advanced gas turbines for powering the aircraft more efficiently, possibly including:

◦ improved combustion emission measures, improvements in cold and hot section materials, and the use of turbine blade/vane technology;

◦ investigation of all-electric, fuel-cell gas turbine and electric gas turbine hybrid propulsion devices; ◦ electric propulsion technologies comprise advanced lightweight motors, motor controllers and power conditioning equipment (icao 2008). 22

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world energy [r]evolution a sustainable world energy outlook

the scenario projects a 50% improvement in specific energy consumption on a per passenger-km basis for future aircrafts in 2050 based on todays energy intensities. figure 12.8 shows the energy intensities in the energy [r]evolution scenario for international, intraregional and domestic aviation.

figure 12.8 | energy intensities (mj/p-km) for air transport in energy [r]evolution scenarios 6.0

finally figure 12.9 shows the final energy consumption by technologies in the reference and in both energy [r]evolution scenarios.

transport of passengers and freight by rail is currently one of the most energy efficient means of transport. however, there is still potential to reduce the specific energy consumption of trains. apart from operational and policy measures to reduce energy consumption like raising the load factor of trains, technological measures to reduce energy consumption of future trains are necessary, too. key technologies are:

4.0 MJ/p-km

passenger and freight trains

5.0

2.0

1.0

â&#x20AC;˘ reducing the total weight of a train as the most significant measure to reduce traction energy consumption. by using lightweight structures and lightweight materials, the energy needed to overcome inertial and grade resistances as well as friction from tractive resistances can be reduced.

International

STATUS QUO

Intra

Domestic

- REFERENCE

2050 ENERGY [R]EVOLUTION note all regions have the same energy intensities due to a lack of regionally differentiated data. numbers shown are the global average.

â&#x20AC;˘ aerodynamic improvements to reduce aerodynamic drag, especially important when running on high velocity. a reduction of aerodynamic drag is typically achieved by streamlining the profile of the train.

figure 12.9 | development of final energy use for aviation by technologies in the reference and both energy [r]evolution scenarios 8,000 7,000 6,000 5,000 PJ/a

3.0

4,000 3,000 2,000 SYNFUELS

1,000

BIOFUELS FOSSIL FUELS

296

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

energy

[r]evolution

the energy [r]evolution scenario uses energy intensity data of (tosca 2011) 23 for electric and diesel fuelled trains in europe as input for our calculations. these data were available for 2009 and as forecasts for 2025 and 2050.

• switch from diesel-fuelled to more energy efficient electrically driven trains. • improvements in the traction system to further reduce frictional losses. technical options include improvements of the major components and in energy management software.

the region-specific efficiency factors and shares of diesel/electric traction traffic performance were used to calculate energy intensity data per region (mj/p-km) for 2012 and up to 2050. the same methodology was applied for rail freight transport.

• regenerative braking to recover waste energy. the energy can either be transferred back into the grid or stored onboard in an energy storage device. regenerative braking is especially effective in regional traffic with frequent stops.

electric trains as of today are about 2 to 3.5 times less energy-intensive than diesel trains depending on the specific type of rail transport, so the projections to 2050 include a massive shift away from diesel to electric traction in the energy [r]evolution 2050 scenario.

• improved space utilisation to achieve more efficient energy consumption per passenger kilometre. the simplest way to achieve this is to transport more passengers per train – in other words, by a higher average load factor, more flexible and shorter trainsets or by the use of double-decker trains on highly frequented routes.

the region-specific efficiency factors for passenger rail take into account higher load factors, for example in china and india. energy intensity for freight rail is based on the assumptions that regions with longer average distances for freight rail (such as the us and russia) and where more raw materials are transported (such as coal) show a lower energy intensity than other regions (fulton & eads 2004). 24 future projections use ten-year historic iea data.

• improved accessory functions, such as for passenger comfort. a high energy efficiency potential lies in the new design of heating and cooling equipment. some strategies for efficiency include adjustments to cabin design, changes to air intakes, and using waste heat from traction. by researching technologies for advanced high-speed trains, the dlr’s ‘next Generation train’ project aims to reduce the specific energy consumption per passenger-kilometre by 50% relative to existing high speed trains in the future.

the calculation of possible future development in the rail transport sector under the descripted assumption leads to the results shown in figure 12.14. under the energy [r]evolution scenarios over 90% of all rail lines are electrified by 2040.

figure 12.10 | development of final energy use for rail transport by technologies in the reference and both energy [r]evolution scenarios 9,000 8,000 7,000

PJ/a

6,000 5,000 4,000 3,000 2,000

ELECTRICITY SYNFUELS

1,000

BIOFUELS FOSSIL FUELS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

references 23 24

tosca (2011): technoloGy opportunities and strateGies toWard climate-friendly transport (reports). (fulton & eads 2004); fulton, l. and G. eads. (2004) iea/smp model documentation and reference case projection. World business council for sustainable development (Wbcsd). http://WWW.Wbcsd.orG/Web/publications/mobility/smp-model-document.pdf.

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world energy [r]evolution a sustainable world energy outlook

heavy and medium duty vehicles (freight by road)

freight transport on the road forms the backbone of logistics in many regions of the world. but apart from air freight transport, it is the most energy-intensive way of moving goods around. however, gradual progress is being made in the fields of drivetrain efficiency, lightweight construction, alternative power trains and fuels and so on. this study projected a major shift in drivetrain market share of medium (mdv) and heavy duty vehicles (hdv) in the energy [r]evolution scenarios in the future. today, the great majority of mdvs and hdvs have internal combustion engines, fuelled mainly by diesel and in mdv also by a small share of gasoline and gas (cnG and lpG). the energy [r]evolution model includes a major shift to electric and fuel cell hydrogenpowered vehicles (fcv) by 2050. the electric mdv stock in the model developed by (dlr 2012) is mainly composed of battery electric vehicles (bev), and a relevant share of hybrid electric vehicles (hev). hybrid electric vehicles will have also displaced conventional internal combustion engines in heavy duty vehicles. in addition to this, both electric vehicles supplied with current via overhead catenary lines and bevs are modelled in the energy [r]evolution scenario for hdv applications.

12 table 12.4 | the world average energy intensities for mdv and hdv currently and 2050 energy [r]evolution scenario 17

status quo

e[r] 2050

mdv

5,02 mj/t-km

2,18 mj/t-km

hdv

1,53 mj/t-km

0,74 mj/t-km

references 25

(Wbscd 2004) World business council for sustainable development.

298

siemens has proved the technical feasibility of the catenary technology for trucks with experimental vehicles in its ehighway project. the trucks are equipped with a hybrid diesel powertrain to be able to operate when not connected to the overhead line. When under a catenary line, the trucks can operate fully electric at speeds of up to 90 km/h. apart from electrically operated trucks fed by an overhead catenary, inductive power supply via induction loops under the pavement could become an option. in addition to the electric truck fleet in the energy [r]evolution scenario, hdv and mdv powered by fuel cells (fcv) were integrated into the vehicle stock, too. fcv are beneficial especially for long haul transports where no overhead catenary lines are available and the driving range of bev would not be sufficient. energy [r]evolution fleet average transport energy intensities for mdv and hdv were derived using region-specific iea energy intensity data of mdv and hdv transport by 2050 (Wbscd 2004), 25 with the specific energy consumption factors of table 12.4 applied to the iea data and matched with the region-specific market shares of the power train technologies. the reduction between the current situation and 2050 in the advanced energy [r]evolution on a per tonne-km basis is then 50-60% for mdv and hdv.

energy

[r]evolution

the dlr’s institute of vehicle concepts conducted special studies to look at future vehicle concepts to see what the potential might be for reducing the overall energy consumption of existing and future trucks when applying energy efficient technologies (dlr 2012)/(dlr 2015). the approach shows the potential of different technologies influencing the energy efficiency of future trucks and also indicates possible cost developments.

• improved hull openings to optimise water flow

inland navigation

• installing new wind energy technologies such as towing kites, flettner turbines and advanced sailing rigs to use wind energy for propulsion

• air lubrication systems to reduce water resistances • improvements in the design and shape of the hull and rudder • waste heat recovery systems to increase overall efficiency • improvement of the diesel engine (e.g. common-rail technology)

technical measures to reduce energy consumption of inland vessels include (van rompuy 2010) 26:

• using solar energy for on-board power demand

• aerodynamic improvements to the hull to reduce friction resistance

adding each technology effectiveness figure stated by (icct 2011), 27 these technologies have a potential to improve energy efficiency of new vessels between 18.4% and about 57%. another option to reduce energy demand of ships is simply to reduce operating speeds. up to 36% of fuel consumption can be saved by reducing the vessel’s speed by 20%. a 25% reduction of fuel consumption for an international marine diesel fleet is achievable by using more efficient alternative propulsion devices only (eyring et al. 2005). 28 up to 30% reduction in energy demand is achievable only by optimising the hull shape and propulsion devices of new vessels (marintek 2000). 29

• improving the propeller design to increase efficiency • enhancing engine efficiency. for inland navigation, we assumed a reduction of 40% of global averaged energy intensity to 0.3 mj/t-km from the current value of 0.5 mj/t-km. marine transport

several technological measures can be applied to new vessels in order to reduce overall fuel consumption in national and international marine transport. these technologies are, for example:

the model assumes a total of 40% energy efficiency improvement potential for international shipping. in order to phase out fossil fuels entirely from marine transports, a mix of energy efficiency (including new wind drives), biofuels and synfuels powered engines are required.

• weather routing to optimise the vessel’s route • autopilot adjustments to minimise steering • improved hull coatings to reduce friction losses

figure 12.11 | development of final energy use for marine transport by technologies in the reference and both energy [r]evolution scenarios 4,000 3,500 3,000

PJ/a

2,500 2,000 1,500 1,000 SYNFUELS

500

BIOFUELS FOSSIL FUELS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

references 26 27 28 29

(van rompuy 2010); Geerts, s., verWerft, b., vantorre, m. and van rompuy, f. (2010): improvinG the efficiency of small inland vessels, proceedinGs of the european inland WaterWay naviGation conference. (icct 2012); icct (2011): reducinG Greenhouse Gas emissions from ships – cost effectiveness of available options. (eyrinG et al. 2005). (marintek 2000); study of Greenhouse emissions from ships, final report to the international maritime orGanZiation.

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world energy [r]evolution a sustainable world energy outlook

box 12.1 | case study: wind powered ships

introduced to commercial operation in 2007, the skysails system uses wind power, which has no fuel costs, to contribute to the motion of large freight-carrying ships, which currently use increasingly expensive and environmentally damaging oil. instead of a traditional sail fitted to a mast, the system uses large towing kites to contribute to the ship’s propulsion. shaped like paragliders, they are tethered to the vessel by ropes and can be controlled automatically, responding to wind conditions and the ship’s trajectory. the kites can operate at altitudes of between 100 and 300 metres, where there are stronger and more stable winds. With dynamic flight patterns, the skysails are able to generate five times more power per square metre of sail area than conventional sails. depending on the prevailing winds, the company claims that a ship’s average annual fuel costs can be reduced by 10% to 35%. under optimal wind conditions, fuel consumption can temporarily be cut by 50%.

the designers say that virtually all sea-going cargo vessels can be retro- or outfitted with the skysails propulsion sytsem without extensive modifications. besides skysails, there are flettner-rotors, new sailing rigs such as dynariG and other wind energy systems for ships in development. Greenpeace supports the implementation of new wind energy technologies to reduce marine fuel demand and to replace bunker fuels and demands for financial support program for research and development (r&d).

many technologies can be used to improve the fuel efficiency of passenger cars. examples include improvements in engines, weight reduction as well as friction and drag reduction.

the impact of the various measures on fuel efficiency can be substantial. hybrid vehicles, combining a conventional combustion engine with an electric engine, have relatively low fuel consumption. the most well-known is the toyota prius, which originally had a fuel efficiency of about 5 litres of gasoline equivalent per 100 km (litre ge/100 km). in 2012, toyota presented an improved version with a lower fuel

figure 12.12 | energy intensities for ldv currently and under the energy [r]evolution in 2050 17

figure 12.13 | ldv occupancy rates currently and under the energy [r]evolution in 2050 17

passenger cars

12.0

2.0

10.0

1.6

8.0 1.2 People

6.0

0.8

4.0 0.4

2.0

STATUS QUO

300

2050 REFERENCE

2050 ENERGY [R]EVOLUTION

STATUS QUO

2050 ENERGY [R]EVOLUTION

AFRICA

INDIA

MIDDLE EAST

CHINA

EASTERN EUROPE/EURASIA

OTHER ASIA

LATIN AMERICA

OECD ASIA OCEANIA

OECD NORTH AMERICA

AFRICA

INDIA

MIDDLE EAST

CHINA

EASTERN EUROPE/EURASIA

OTHER ASIA

LATIN AMERICA

OECD ASIA OCEANIA

OECD NORTH AMERICA

OECD EUROPE

0 OECD EUROPE

Litres GE/V-km

on the first voyage of the beluga skysails, a 133 m long specially-built cargo ship, the towing kite propulsion system was able to temporarily substitute for approximately 20% of the vessel’s main engine power, even in moderate winds. the company is now planning a kite twice the size of this 160m 2 pilot.

energy

[r]evolution

consumption of 4.3 litres ge/100 km. new lightweight materials, in combination with new propulsion technologies, can bring fuel consumption levels down to 1 litre ge/100 km. the figure 12.12 gives the energy intensities calculated using power train market shares and efficiency improvements for LDv in the Reference scenario and in the energy [R]evolution scenario. the energy intensities for car passenger transport are currently highest in oecD north america and lowest in oecD europe. the Reference scenario shows a decrease in energy intensities in all regions, but the division between highest and lowest will remain the same, although there will be some convergence.

we have assumed that the occupancy rate for cars remains nearly the same as in 2009, as shown in figure 12.13. table 12.5 summarises the energy efficiency improvement for passenger transport in the energy [R]evolution 2050 scenario and table 12.6 shows the energy efficiency improvement for freight transport in the advanced energy [R]evolution 2050 scenario. figure 12.14 provides an overview about electric transport vehicles for urban areas. the figures are results of a specific research commissioned from greenpeace international for public and energy efficient individual transport technologies.

table 12.5 | technical efficiency pOtential fOr wOrld passenger transpOrt 17

table 12.6 | technical efficiency pOtential fOr wOrld freight transpOrt 17

mJ/p-km

mJ/t-km

status QuO

e[r] 2050

status QuO

e[r] 2050

LDv

1.5

0.3

mDv

4.8

2.7

aiR (Domestic)

2.5

1.2

hDv

1.6

0.8

buses

0.5

0.3

fReight RaiL

0.2

0.1

mini-buses

0.5

0.3

inLanD navigation

0.5

0.3

two wheeLs

0.5

0.3

thRee wheeLs

0.7

0.5

passengeR RaiL

0.4

0.2

figure 12.14 | Overview electricity demand Of transpOrt technOlOgies per 100 passenger kilOmeters

AERIAL ROPEWAY COMMUTER TRAIN METRO LIGHT RAIL TRAIN TROLLEYBUS FCE BUS (H2 OUT OF ELECTROLYSIS) FCE MINIBUS (H2 OUT OF ELECTROLYSIS) BE BUS BE MINI BUS FCEV (H2 OUT OF ELECTROLYSIS) PASSENGER CAR BEV C PASSENGER CAR BEV B PASSENGER CAR BEV A ELECTRIC RICKSHAW ELECTRIC MOTORBIKE ELECTRIC SCOOTER PEDELEC

/ E-BIKE 0

Electrical energy demand (kWh/100 pass-km)

source DLR 2015.

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world energy [r]evolution a sustainable world energy outlook

table 12.7 | selected parameters fOr vehicle technOlOgies fOr city applicatiOns

transport mode characteristics

indvidual transport systems e-bikes

scooteRs

motoRbikes

2-wheeLeR

freight

Rickshaw

eLectRic n1 fReight vehicLe

caR

3-wheeLs

smaLL

meDium

LaRge

road

battery

fuel cell

1 (1-2) 18 (14-22) 50 30-60 1.03

1 (1-3) 45 (25-60)

5+1 (4-7)+1 35 (20-50) 80 (40-150) 8

LaRge battery

fuel cell

0.600 (0.306-1.400) 110 (45-130) 150 (65-170) 18

0.600 (0.306-1.400) 110 (45-130) 425 (281-425) 44

transport capacity passengeRs

aveRage min

speeD

max

passengeRs peR vehicLe

aveRage

km/h

min Range

max

aveRage

min

max

tank to wheeL eneRgy consumption

aveRage

kwheL/100 vkm

vehicLe DemanD

min

kwheL/100 vkm

max

2.0

170 (150-240) 190 (50-300) 4.5-5.0

(1.0-2.5)

2 4 5 4 (2-4) (4-5) (4-7) (4-5) 100 115 140 166 (45-130) (60-150) (120-180) (160-170) 130 150 180 480 (40-160) (100-220) (150-320) (380-580) 15 16 17 34

(6-10)

(12-20)

(10-22)

(13-21)

(32-35)

6.8

20.9

(12-26)

energy demand eLectRicity consumption peR passengeR

aveRage

kwheL/100 pass-km

2.5

4.8

8.3

6.4

assumeD occupation Rates in peRsons

min

kwheL/100 pass-km

(0,8-1,5)

(2,1-2,95)

(4,5-5)

(3-5)

(6,7-11,1)

(4-8,8)

850 (410 – 2,000)

25,000 (9,30065,000)

36,000 (8,000 c70,000)

45,000 (32,00077,000)

15 15

16 >8

max

economics vehicLe pRice

aveRage min

Life time vehicLe

max

aveRage min

Life time of batteRy fueL ceLL

max

us$2014 us$2014 km a (yeaRs)

aveRage

a (yeaRs)

min

max

700 650 (400-2,000) (370-860) 15,000 50,000 10 3-5

18,000 (9,90039,000) 97,000 – 121,000 10

10 2-6

(5,2-8,4) (19,7-21,5)

aveRage min / max

cycLes

35,000 (29,60060,000)

86,200

12 8

130

58,000 (32,00077,000)

300-1,000 (300-1,000)

1,200

650

130 (1,000-4,500)

transport mode characteristics

public transport bus

mini bus

small

large

road

battery

fuel cell

battery

fuel cell

bus

tRoLLey-bus

mini bus

tRams

metRos

commuteR tRains

aeRiaL Ropeway systems

rail

overhead lines

transport capacity

tank to wheeL eneRgy consumption

aveRage

kwheL/100 vkm

15 (10-30) 300 200-600 70 (60-80) 130 (80-200) 30

vehicLe DemanD

min

kwheL/100 vkm

(17-44)

(43-110)

(98-188)

(245-470)

(175-350)

(240-750)

(560-1,840)

(1,400-2,500)

(6-10)

18.5

4.5

13.5

4.9

3.8

4.8

(10-18,8)

(3,3-6,5)

(2-5)

(1,8-5,8)

(3,5-6,3)

(15-25)

4,000,000 (3,500,0004,200,000)

9,000,000 (6,000,00015,000,000)

1,200,0000 (8,000,00015,000,000)

30 (20-40)

25 (20-32)

120 (70-200)

70 (20-150)

12 (5-20)

passengeRs

aveRage

passengeRs

peR vehicLe

min

max

aveRage min speeD

max

passengeRs peR houR

aveRage

km/h

min Range

max

aveRage

min

max

15 75 75 135 300 800 1,000 (10-30) (60-80) (60-80) (120-150) (140-500) (200-1,500) (300-1,500) 300 1,500 1,500 2,700 6,000 16,000 20,000 4,000 200-600 1,200-1,600 1,200-1,600 2,400-3,000 2,800-10,000 (4,000-24,000) (6,000-30,000) (3,000-6,000) 70 90 90 80 70 80 100 27 (60-80) (80-100) (80-100) (60-100) (60-80) (60-90) (80-140) (21-31) 250 250 350 not LimiteD not LimiteD not LimiteD not LimiteD not LimiteD (150-500) (150-300) (250-400) 75 135 340 263 450 1280 1,900 8

energy demand eLectRicity consumption peR passengeR

aveRage

kwheL/100 pass-km

4.75

assumeD occupation Rates in peRsons

min

kwheL/100 pass-km

(2,75-7)

(10,8-26,9) (3,25-6,25)

80,000 (30,000200,000)

250 (150,000800,000)

12 (10-20) 8 ( 3-15)

12 (10-20) 4 ( 3-5)

max

economics vehicLe pRice

aveRage min

Life time vehicLe

max

aveRage min

fueL ceLL

max

us$2014 us$2014 km a (yeaRs)

aveRage

a (yeaRs)

min

max

400,000 1,000,000 900,000 (200,000- (600,000- (600,0001,000,000) 1,500,000) 1,300,000) 12 (10-20) 8 ( 3-15)

12 (10-20) 4 ( 3-5)

20 (15-25)

km cycLes infRastRuctuRe cost

302

musD/km

energy

[r]evolution

12.3 prOJectiOn Of the future car market

12.3.2 prOJectiOn Of the future vehicle segment split

12.3.1 prOJectiOn Of the future technOlOgy mix

the scenario is constructed to disaggregate the light-duty vehicle sales into three segments: small, medium and large vehicles. this model shows the effect of ‘driving small urban cars’ to see if they are suitable for megacities of the future. the size and co 2 emissions of the vehicles are particularly interesting in the light of the enormous growth predicted in the LDv stock. for our purposes, we could divide up the numerous car types as follows:

• the medium sized bracket includes car derived vans and small station wagons, upper medium class, midsize cars and station wagons, executive class, compact passenger vans, car derived pickups, medium suvs, 2wD and 4wD. • the large car bracket includes all kinds of luxury class, luxury multi-purpose vehicles, medium and heavy vans, compact and full-size pickup trucks (2wD, 4wD), standard and luxury suvs. in addition, we looked at light duty trucks in north america and light commercial vehicles in china separately.

2012 2050

MIDDLE EAST

INDIA

GRID CONNECTABLE AUTONOMOUS HYBRIDS

2012 2050

2012 2050 CHINA

CONVENTIONAL

AFRICA

2012 2050

AFRICA

INDIA

0 MIDDLE EAST

0 CHINA

EASTERN EUROPE/EURASIA

OTHER ASIA

LATIN AMERICA

OECD ASIA OCEANIA

OECD NORTH AMERICA

EASTERN EUROPE/EURASIA

2012 2050

OTHER ASIA

2012 2050

LATIN AMERICA

2012 2050

OECD ASIA OCEANIA

2012 2050

100

OECD NORTH AMERICA

figure 12.16 | assumed vehicle sales by segment currently and 2050 under the energy [r]evOlutiOn 17

100

OECD EUROPE

figure 12.15 | sales share Of cOnventiOnal ice, autOnOmOus hybrid and grid-cOnnectable vehicles in 2050 17

• the small sized bracket includes compact and subcompact cars, micro and subcompact vans and small suvs.

2012 2050

in the future, it may not be possible to power cars for all purposes by rechargeable batteries only. therefore, hydrogen and synfuels are required as a renewable fuel especially for larger cars including light commercial vehicles. biofuels and synfuels will be used in other applications where a substitution is even harder than for cars. figure 12.15 shows the share of fuel cell vehicles (autonomous hybrids) and full battery electric vehicles (grid connectable) in 2050 in the new vehicle market according to the projections in (DLR 2012).

• the very small car bracket includes city, super-mini, minicompact cars as well as one and two seaters.

OECD EUROPE

achieving the substantial co 2 -reduction targets in the energy [R]evolution scenario would require a radical shift in fuels for cars and other light duty vehicles. for viable, full electrification based on renewable energy sources, the model assumes that petrol and diesel fuelled autonomous hybrids and plug-in hybrids that we have today are phased out already by 2050 in the advanced energy [R]evolution scenario. thus, two generations of hybrid technologies will pave the way for the complete transformation to light duty vehicles with full battery electric or hydrogen fuel cell powertrains. this is the only way that is efficient enough for the use of renewable energy to reach the co 2 -targets in the car sector.

LARGE MEDIUM SMALL

303

world energy [r]evolution a sustainable world energy outlook

12.3.3 prOJectiOn alternative fuels

the

future

switch

a switch to renewable fuels in the car fleet is one of the cornerstones of the low co 2 car scenario, with the most prominent element the direct use of renewable electricity in cars. the different types of electric and hybrid cars, such as battery electric and plug-in hybrid, are summarised as ‘plug-in electric’. their introduction will start in industrialised countries between 2015 and 2020, following an s-curve pattern, and are projected to reach 35-40% of total LDv sales in the eu, north america and the oecD asia oceania by 2050. Due to the higher costs of the technology and renewable electricity availability, we have slightly delayed progress in other countries. more cautious targets are applied for africa. there are huge differences in forecasts for the growth of vehicle sales in developing countries. in general, the increase in sales and thus vehicle stock and ownership is linked to the forecast of gDp growth, which is a well-established correlation in the science community. however, this scenario analysis found that technology shift in LDvs alone – although linked to enormous efficiency gains and fuel switch - is not enough to fulfil the ambitious energy [R]evolution co 2 targets. a slowdown of vehicle sales growth and a limitation or even reduction in vehicle ownership per capita compared to the Reference scenario was thus required. global urbanisation, the on-going rise of megacities, where space for parking is scarce, and the trend starting today that ownership of cars might not be seen as desirable as in the past draws a different scenario of the future compared to the reference case. going against the global pattern of a century, this development would have to be supported by massive policy intervention to promote modal shift and alternative forms of car usage. for megacities, greenpeace commissioned an additional specific research, key results are presented in table 12.7.

304

12.3.4 prOJectiOn Of the future kilOmetres driven per year

until a full shift from fossil to renewable fuels has taken place, driving on the road will create co 2 emissions. thus, driving less contributes to our target for emissions reduction. however, this shift does not have to mean reduced mobility equally because there are many excellent opportunities for shifts from individual passenger road transport towards less co 2 -intensive public and non-motorised transport. Data on average annual kilometres driven are uncertain in many world regions except for north america, europe and recently china. the scenario starts from the state-of-the-art knowledge on how LDvs are driven in the different world regions and then projects a decline in car usage. this is a further major building block in the low carbon strategy of the energy [R]evolution scenarios, which goes hand in hand with new mobility concepts like co-modality and car-sharing concepts. in 2050, policies supporting the use of public transport and environmental friendly modes are anticipated to be in place in all world regions. our scenario of annual kilometres driven (akD) by LDvs is shown in figure 12.17. in total, akD fall almost by one quarter until 2050 compared to 2012.

figure 12.17 | develOpment Of the average annual ldv kilOmetres driven per wOrld regiOn under the energy [r]evOlutiOn 17 25,000

20,000

15,000 Km

in examining the segment split, we have focused most strongly on the two world regions which will be the largest emitters of co 2 from cars in 2050: north america and china. in north america today, the small vehicle segment is almost non-existent. we found it necessary to introduce here small cars substantially, triggered by rising fuel prices and possibly vehicle taxes. for china, we have anticipated a similar share of the mature car market as for europe and projected that the small segment will grow by 3% per year at the expenses of the larger segments in the light of rising mass mobility. the segment split is shown in figure 12.16.

10,000

5,000

0 2012

2015

2020

2025

2030

2035

2040

AFRICA

INDIA

MIDDLE EAST

EASTERN EUROPE/EURASIA

LATIN AMERICA

OECD EUROPE

OTHER ASIA

OECD ASIA OCEANIA

CHINA

OECD NORTH AMERICA

2045

2050

energy

[r]evolution

figure 12.18 shows the final energy consumption by technologies under 3 scenarios for road transport. the implementation of new alternatives drives – mainly in combination with electric machines – start to have an impact after 2025 and can take over a significant share after 2035. synfuels, however are believed to be equally important especially for large vehicles including trucks and busses.

12 figure 12.18 | develOpment Of final energy use fOr rOad transpOrt by technOlOgies in the reference and bOth energy [r]evOlutiOn scenariOs 140,000

120,000

100,000

PJ/a

80,000

60,000 ELECTRICITY

40,000

HYDROGEN NATURAL GAS SYNFUELS

20,000

BIOFUELS FOSSIL FUELS

0 REF E[R] ADV E[R]

REF E[R] ADV E[R]

2012

2020

2025

2030

2040

2050

305

world energy [r]evolution a sustainable world energy outlook

12.4 cOnclusiOn in a business as usual world we project a high rise of transport energy demand until 2050 in all world regions in the Reference scenario, which is fuelled especially by fast developing countries like china and india. the aim of this chapter was therefore to show ways to reduce energy demand in general and the dependency on climate damaging fossil fuels in the transport sector. the findings of our scenario calculations show that a combination of behavioural changes and tremendous technical efforts is needed in order to reach the ambitious energy reduction goals of the energy [R]evolution scenario: • a decrease of passenger and freight kilometres on a per capita base

• a gradual decrease of all modes’ energy intensities by technological progress • a modal shift from aviation to high speed rail and from road freight to rail freight. these measures must of course be accompanied by major efforts in the installation and extension of the necessary infrastructures as for example in railway networks hydrogen and battery charging infrastructure for electric vehicles and an electrification of highways. figure 12.19 shows the development of the regional shares of transport demands by region under both energy [R]evolution scenarios between 2012 and 2050. the main difference is a more equal distribution of the transport energy demand across all regions in regard to transport energy per person.

• a massive shift to electrically and hydrogen powered vehicles whose energy sources may be produced by renewables

figure 12.19 | wOrld final energy use by regiOn 2012 – 2050 – energy [r]evOlutiOn scenariOs 17 2012

2050

OECD ASIA

OCEANIA, CHINA,

20%

OTHER ASIA, INDIA,

6% MIDDLE EAST, 5%

306

OECD ASIA

OECD NORTH AMERICA,

LATIN AMERICA,

OECD EUROPE,

14%

21%

EASTERN EUROPE/EURASIA, AFRICA,

OCEANIA, CHINA,

OTHER ASIA,

INDIA,

21%

10%

12% MIDDLE EAST, 6%

OECD NORTH AMERICA, LATIN AMERICA,

OECD EUROPE,

10%

13%

EASTERN EUROPE/EURASIA, AFRICA,

10%

g lo s s a ry, r e f e r e n c e s & a p p e n d i x references

glOssary Of cOmmOnly used terms and abbreviatiOns

annexes

13 may the (data) force be with you”

“

image located near the equator in central africa, the nyamuragira and nyiragongo volcanoes are often obscured from satellite view by clouds. but on february 9, 2015, clear skies afforded an unobstructed view from space of two plumes venting from the volcanic duo in the democratic republic of the congo. occasionally, nyiragongo spews more than just steam and volcanic gases. eruptions of fluid lava from the volcano in 1977 and 2002 had deadly consequences for the city of goma, which lies about 15 kilometers (9 miles) south of the volcano.

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world energy [r]evolution a sustainable world energy outlook

13.1 references intrOductiOn 1 2

Link to RepoRt: http://www.mc-gRoup.com/the-RenewabLe-eneRgy-RevoLution/ see http://www.caRbontRackeR.oRg/news/bank-of-engLanDs-momentous-move-on-cLimatechange/ anD http://www.bLoombeRg.com/news/aRticLes/2014-12-18/bankeRs-see-1-tRiLLionof-investments-stRanDeD-in-the-oiL-fieLDs

executive summary 1 2

chapter 1 1

2 3 4 5 6 7 8

(ipcc-aR5-spm) inteRnationaL paneL on cLimate change – 5th assessment RepoRt; cLimate change 2014, summaRy fotR poLicy makeRs; http://ipcc.ch/pDf/assessmentRepoRt/aR5/syR/aR5_syR_finaL_spm.pD (wnisR 2015) woRLD nucLeaR inDustRy status RepoRt 2015, mycLe schneiDeR, antony fRoggatt et. aL.; paRis / LonDon 2015. (Ren 21-2015); gLobaL status RepoRt RenewabLes 2015, Ren 21; paRis. atomausstiegsgesetZ – 30 June 2011. (iea-weo-sR-2015) inteRnationaL eneRgy agency; woRLD eneRgy outLook 2015 – speciaL RepoRt eneRgy anD cLimate; June 2015; paRis/fRance. ‘waste management in the nucLeaR fueL cycLe’, woRLD nucLeaR association, infoRmation anD issue bRief, febRuaRy 2006 (www.woRLD-nucLeaR.oRg/info/inf04.htm). mohameD eLbaRaDei, ‘towaRDs a safeR woRLD’, economist, 18 octobeR 2003. ipcc woRking gRoup ii, ‘impacts, aDaptations anD mitigation of cLimate change: scientifictechnicaL anaLyses’, 1995.

3 4 5 6

chapter 5 1 2 3 4 5 6

chapter 2 1

chapter 3

1 2

3 4

Ren21 – RenewabLes 2015 – gLobaL status RepoRt; June 2015, paRis / fRance.

6 7 8 9

11 12

13 14 15 16 17 18

19 20 21

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14 15 16

18 19

22 23 24 25 26

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inteRnationaL eneRgy agency, ‘woRLD eneRgy outLook 2014’, 2014. ‘eneRgy [R]evoLution: a sustainabLe woRLD eneRgy outLook’, gReenpeace inteRnationaL, 2007, 2008, 2010 anD 2012. eneRgy [R]evoLution: a sustainabLe woRLD eneRgy outLook’, gReenpeace inteRnationaL, 2012. gRaus, keRmeLi 2012: pRoJect RepoRt - eneRgy DemanD pRoJections foR eneRgy [R]evoLution 2012. utRecht univeRsity, maRch 2012. gLobaL biomass potentiaLs - ResouRces, DRiveRs anD scenaRio ResuLts, thRän, D., seiDenbeRgeR, t. et aL., DbfZ 2010. e.g. Ren21 2015: RenewabLes 2015 - gLobaL status RepoRt; ewea 2015: the euRopean offshoRe winD inDustRy - key tRenDs anD statistics 2014, anD otheR RegionaL statistics anD Data souRces. e.g. pietZckeR, stetteR et aL. 2014: using the sun to DecaRboniZe the poweR sectoR: the economic potentiaL of photovoLtaics anD concentRating soLaR poweR, appLieD eneRgy, voLume 135, 15 DecembeR 2014, pages 704–720; Deng et aL. 2015: Quantifying a ReaListic, woRLDwiDe winD anD soLaR eLectRicity suppLy, gLobaL enviRonmentaL change 31 (2015) 239-252; DLR 2015: Remix enDat moDeLLing ResuLts pRoviDeD by the geRman aeRospace centeR, institute of engineeRing theRmoDynamics. e.g. epia 2014: gLobaL maRket outLook foR soLaR poweR / 2015-2019,; gwec 2014: gLobaL winD RepoRt 2014; wec 2015: woRLD eneRgy ResouRces - chaRting the upsuRge in hyDRopoweR DeveLopment 2015, anD avaiLabLe RegionaL maRket DeveLopment pRoJections. DLR 2012: pRoJect RepoRt - tRanspoRt scenaRio buiLDing in the e[R] 2012. pagenkopf, J., schmiD, s., fRieske, b., geRman aeRospace centeR (DLR), institute of vehicLe concepts; stuttgaRt, geRmany. DLR 2015: pRoJect RepoRt - aLteRnative tRanspoRt technoLogies foR megacities; geRman aeRospace centeR (DLR), institute of vehicLe concepts; stuttgaRt, geRmany. ‘eneRgy baLances of non-oecD countRies’ anD ‘eneRgy baLances of oecD countRies’, iea, 2014. foR statisticaL Reasons, isRaeL is incLuDeD in oecD euRope. weo 2014 Defines the Region „oecD ameRicas” as usa, canaDa, mexico, anD chiLe. in contRast to that the eneRgy [R]evoLution scenaRios caLcuLate chiLe with Latin ameRica to maintain RegionaL integRity. cypRus, gibRaLtaR anD maLta aRe aLLocateD to easteRn euRope/euRasia foR statisticaL Reasons. Latin ameRica incLuDes chiLe, in contRast to weo 2014. woRLD eneRgy outLook 2014 – eLectRicity access Database, http://www.woRLDeneRgyoutLook.oRg/ResouRces/eneRgyDeveLopment/eneRgyaccessDatab ase/ woRLD eneRgy outLook 2014 – tRaDitionaL use of soLiD biomass foR cooking, http://www.woRLDeneRgyoutLook.oRg/ResouRces/eneRgyDeveLopment/eneRgyaccessDatab ase/ woRLD popuLation pRospects: the 2012 Revision (meDium vaRiant)’, uniteD nations, popuLation Division, DepaRtment of economic anD sociaL affaiRs (unDp), 2013 noRDhaus, w, ‘aLteRnative measuRes of output in gLobaL economic-enviRonmentaL moDeLs: puRchasing poweR paRity oR maRket exchange Rates?’, RepoRt pRepaReD foR ipcc expeRt meeting on emission scenaRios, us-epa washington Dc, JanuaRy 12-14, 2005. iea 2014: poweR geneRation in the new poLicies anD 450 scenaRios - assumeD investment costs, opeRation anD maintenance costs anD efficiencies in the iea woRLD eneRgy investment outLook 2014, Data fiLe DownLoaD: http://www.woRLDeneRgyoutLook.oRg/investment/ neiJ, L, ‘cost DeveLopment of futuRe technoLogies foR poweR geneRation - a stuDy baseD on expeRience cuRves anD compLementaRy bottom-up assessments’, eneRgy poLicy 36 (2008), 2200-2211. www.neeDs-pRoJect.oRg epia 2014: gLobaL maRket outLook foR soLaR poweR / 2015 – 2019. gwec 2014: gLobaL winD RepoRt 2014. g.J. DaLton, t. Lewis (2011): peRfoRmance anD economic feasibiLity anaLysis of 5 wave eneRgy Devices off the west coast of iReLanD; ewtec 2011. oLson, o. et aL. (2010): wp3-wooD fueL pRice statistics in euRope - D.31. soLutions foR biomass fueL maRket baRRieRs anD Raw mateRiaL avaiLabiLity. eubionet3. uppsaLa, sweDen, sweDish univeRsity of agRicuLtuRaL sciences. own assumptions, baseD on Data fRom the heLmhoLtZ aLLiance pRoJect “synthetic LiQuiD hyDRocaRbons” (synkws), DLR, 2015. (mcg 2015); RenewabLe eneRgy RevoLution” – pubLisheD maRch 16, 2015 (mcg 2015) http://www.mc-gRoup.com/wp-content/upLoaDs/2015/03/mcg-RenewabLe-eneRgy-RevoLutioninfogRaphic.pDf

chapter 7 chapter 4 1 1

(swiss Re 2011), an intRoDuction to RenewabLe eneRgy infRastRuctuRe investing; contact: RobeRt nef; co-heaD investoR soLutions; RobeRt_nef@swissRe.com; +41 43 285 2121newabLe eneRgy infRastRuctuRe investing - swiss Re pRivate eQuity paRtneRs; septembeR 2011. souRces incLuDe: inteRgoveRnmentaL paneL on cLimate change (ipcc) (2011) speciaL RepoRt on RenewabLe eneRgy souRces anD cLimate change mitigation (sRRen), 15th June 2011. uniteD nations enviRonment pRogRamme (unep), bLoombeRg new eneRgy finance (bnef) (2015). gLobaL tRenDs in RenewabLe eneRgy investment 2015, maRch 2015.

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RutovitZ, J., Dominish, e. anD Downes, J. 2015. caLcuLating gLobaL eneRgy sectoR Jobs: 2015 methoDoLogy upDate. pRepaReD foR gReenpeace inteRnationaL by the institute foR sustainabLe futuRes, univeRsity of technoLogy syDney. RutovitZ, J., Dominish, e. anD Downes, J. 2015. caLcuLating gLobaL eneRgy sectoR Jobs: 2015 methoDoLogy upDate. pRepaReD foR gReenpeace inteRnationaL by the institute foR sustainabLe futuRes, univeRsity of technoLogy syDney. Data is in tonnes coaL eQuivaLent, to stanDaRDise between Regions. bp statisticaL Review of woRLD eneRgy 2015.

energy

[r]evolution

chapter 8 1

2 3 4 5

(Ren21 – 2015); RenewabLes 2015 -gLobaL status RepoRt; annuaL RepoRting on RenewabLes: ten yeaRs of exceLLence; Ren21; c/o unep; 15, Rue De miLan, f-75441 paRis ceDex 09, fRance; June 2015; www.Ren21.net. (oecD): oRganisation foR economic co-opeRation anD DeveLopment. (nbsc 2015);pRess ReLease fRom 15th apRiL 2015; http://www.stats.gov.cn/engLish/pRessReLease/201504/t20150415_712435.htmL (usa – eneRgy.gov 2015): officiaL infoRmation fRom the website of the us goveRnment: http://eneRgy.gov/savings/RenewabLe-eLectRicity-pRoDuction-tax-cReDit-ptc whiLe the officiaL statistic of the gLobaL anD chinese winD inDustRy associations (gwec/cReia) aDDs up to 18,900 mw foR 2010, the nationaL eneRgy buReau speaks about 13,999 mw. the DiffeRences between souRces aRe Due to the time of gRiD connection, as some tuRbines weRe instaLLeD in the Last months of 2010 but onLy connecteD to the gRiD in 2011. these effects aLso might aRise in the foLLowing yeaR tiLL 2014. (teske 2015) maRket anaLysis baseD on statistics of pLatts, Ren21, gwec, soLaRpoweReuRope.

chapter 9 1 2

3 4 5 6 7

8 9 10

11 12

15 16

18 19

(iea 2014) woRLD eneRgy outLook 2014; inteRnationaL eneRgy agency; 9 Rue De La féDéRation; 75739 paRis ceDex 15, fRance; www.iea.oRg; novembeR 2014, isbn: 978 92 64 20804 9 (gea 2012): gLobaL eneRgy assessment - towaRD a sustainabLe futuRe, cambRiDge univeRsity pRess, cambRiDge, uk anD new yoRk, ny, usa anD the inteRnationaL institute foR appLieD systems anaLysis, LaxenbuRg, austRia; www.gLobaLeneRgyassessment.oRg (bp 2011) statisticaL Review of the woRLD - 2011. (bp 2015 – statisticaL Review of the woRLD – 2015; www.bp.com. The IndependenT, 10 DecembeR 2007. (css 2014) centeR foR sustainabLe systems; univeRsity of michigan. 2014. “unconventionaL fossiL fueLs factsheet.” pub. no. css13-19. octobeR 2014. (ingaa 2008)inteRstate natuRaL gas association of ameRica (ingaa), “avaiLabiLity, economics anD pRoDuction potentiaL of noRth ameRican unconventionaL natuRaL gas suppLies”, novembeR 2008. (oecD nea-2014) uRanium 2014:ResouRces, pRoDuction anD DemanD; oecD nucLeaR eneRgy agency; 12, bouLevaRD Des ÎLes; 92130 issy-Les-mouLineaux, fRance; www.oecD-nea.oRg. (oecD nea 2003) ‘uRanium 2003: ResouRces, pRoDuction anD DemanD’. (Res 2007) ‘pLugging the gap - a suRvey of woRLD fueL ResouRces anD theiR impact on the DeveLopment of winD eneRgy’, RenewabLe eneRgy systems LtD (Res); beaufoRt couRt egg faRm Lane; kings LangLey heRts wD4 8LR; uniteD kingDom; web: www.Res-gRoup.com. wbgu (geRman aDvisoRy counciL on gLobaL change). (sRRen 2011) ipcc, 2011: ipcc speciaL RepoRt on RenewabLe eneRgy souRces anD cLimate change mitigation. pRepaReD by woRking gRoup iii of the inteRgoveRnmentaL paneL on cLimate change [o. eDenhofeR, R. pichs-maDRuga, y. sokona, k. seyboth, p. matschoss, s. kaDneR, t. ZwickeL, p. eickemeieR, g. hansen, s. schLÖmeR, c. von stechow (eDs)]. cambRiDge univeRsity pRess, cambRiDge, uniteD kingDom anD new yoRk, ny, usa, 1075 pp. gReenpeace Does not necessaRiLy vaLue feeD above eneRgy. the Livestock sectoR is LaRgeLy unsustainabLe anD shouLD be stRongLy DecReaseD in most paRts of the woRLD. howeveR, the competition effect of a poLicy DRiven bioeneRgy maRket with the fooD anD feeD maRket LeaD to uncontRoLLabLe negative effects, mainLy inDiRect LanD use change (iLuc), which can unDeRmine the enviRonmentaL benefits of bioeneRgy. the caLcuLation must incLuDe emissions fRom cuLtivation, extRaction, pRocessing, stoRage, tRanspoRt, anD smokestack emissions (buRning biomass is not caRbon neutRaL). when buRning biomass, the net gReenhouse gas emissions oveR a peRioD of 20 yeaRs must be accounteD foR, against the RefeRence scenaRio of not using the biomass foR bioeneRgy. gRassLanDs stoRe appRoximateLy 34% of the gLobaL stock of caRbon in teRRestRiaL ecosystems whiLe foRests stoRe appRoximateLy 39%. gReenpeace (2013), iDentifying high caRbon stock (hcs) foRest foR pRotection, http://m.gReenpeace.oRg/inteRnationaL/gLobaL/inteRnationaL/bRiefings/foRests/2013/hcsbRiefing-2013.pDf at this moment, onLy the fsc pRincipLes anD cRiteRia aRe sufficient to guaRantee ResponsibLe management of foRests. see www.fsc.oRg. this appLies to aLL wooD pRoDucts, whetheR bioeneRgy is invoLveD oR not. obviousLy this appLies to aLL agRicuLtuRe, whetheR bioeneRgy pRoDuction is invoLveD oR not. uniteD nations (un) committee on woRLD fooD secuRity (cfs) (2012), voLuntaRy guiDeLines on the ResponsibLe goveRnance of tenuRe of LanD , fisheRies anD foRests in the context of nationaL fooD secuRity, http://www.fao.oRg/cfs/cfs-home/cfs-LanD-tenuRe/en/ . inteRnationaL LabouR oRganiZation (iLo), inteRnationaL LabouR stanDaRDs, http://www.iLo.oRg/gLobaL/stanDaRDs/Lang--en/inDex.htm.

chapter 10 1 2

3 4 5 6 7 8 9 10 11 12 13 14

(iea 2015) eneRgy cLimate anDchange; woRLD eneRgy outLook speciaL RepoRt 2015; inteRnationaL eeneRgy agency, 9 Rue De La féDéRation, 75739 paRis ceDex 15, June 2015. (iea-coaL onLine 2011) http://www.coaLonLine.oRg/site/coaLonLine/content/vieweR?LogDociD=81996&phyDociD=7800 &fiLename=780000023.htmL (wca 2015) woRLD coaL association 2015; http://www.woRLDcoaL.oRg/coaL-theenviRonment/coaL-use-the-enviRonment/impRoving-efficiencies/ (iea-etp 2014) eneRgy technoLogy peRspective – haRnessing eLectRicities potentiaL; iea may 2014. (iea tcep 2015); tRacking cLean eneRgy pRogRess 2015 - eneRgy technoLogy peRspectives 2015, iea input to the cLean eneRgy ministeRiaL, June 2015. (teske – ccs 1) LeaD authoRs own caLcuLation: 32.3 bn tonnes co2 / 8760h = 3.6 bn tonnes /h (gpi-fh 2008) “faLse hope”; gReenpeace inteRnationaL; emiLy Rochon et. aL.; may 2008; gReenpeace inteRnationaL; ottho heLDRingstRaat 5; 1066 aZ amsteRDam; the netheRLanDs. (scheiDeR/fRoggatt 2015) the woRLD nucLeaR inDustRy – status RepoRt 2015; paRis, LonDon, JuLy 2015; © a mycLe schneiDeR consuLting pRoJect. (iaea 2004; wno 2004). (hoffmann/teske 2012) pRepaRation foR epia/gReenpeace soLaRgeneRation RepoRt seRies(eDition i – vi). (epia 2011) soLaRgeneRation 6 – epia-gReenpeace RepoRt; euRopean photovoLtaic inDustRy association (epia); gpi, bRusseLs / amsteRDam; 2011. (esteLa 2015) concentRateD soLaR poweR outLook 2015; euRopean soLaR theRmaL eLectRic association; bRusseLs septembeR 2015. (ewea 2009) winD eneRgy – the facts; euRopean winD eneRgy association; bRusseLs/beLgium ; http://www.winD-eneRgy-the-facts.oRg). ewea 2009.

15 (statistica 2015); onLine statisticaL ReseaRch tooL; http://www.statista.com/statistics/263905/evoLution-of-the-hub-height-of-geRman-winDtuRbines/. 16 (ewea 2014) winD eneRgy scenaRios foR 2020; euRopean winD eneRgy association; JuLy 2014; www.ewea.oRg. 17 (gwec, 2015) gLobaL winD RepoRt 2014 – annuaL maRket upDate; gLobaL winD eneRgy counciL, bRusseLs/beLgium, www.gwec.net ; maRch 2015. 18 caRbon tRust, 2008b; snyDeR anD kaiseR, 2009b; twiDeLL anD gauDiosi, 2009. 19 (ewea, 2010a). 20 musiaL, 2007; caRbon tRust, 2008b. 21 (gowef 2014); cost ReDuction potentiaLs of offshoRe winD poweR in geRmany; pRognos / fichtneR, commissioneD by: the geRman offshoRe winD eneRgy founDation; anDReas wagneR; oLDenbuRgeR stR. 65; 26316 vaReL; geRmany; www.offshoRestiftung.De 22 (ewea-7-2013); Deep wateR - the next step foR offshoRe winD eneRgy; euRopean winD eneRgy association - JuLy 2013; isbn: 978-2-930670-04-1. 23 (ipcc-aR5-spm) inteRnationaL paneL on cLimate change – 5th assessment RepoRt; cLimate change 2014, summaRy fotR poLicy makeRs; http://ipcc.ch/pDf/assessmentRepoRt/aR5/syR/aR5_syR_finaL_spm.pDf 24 (faaiJ 2006). 25 (yokoyama anD matsumuRa 2008). 26 (kiRkeLs anD veRbong 2011). 27 (iea bio-2009) bioeneRgy – a sustainabLe anD ReLiabLe eneRgy souRce main RepoRt; inteRnationaL eneRgy agency 2009. 28 (ipcc-sRRen 2012); chapteR 4 geotheRmaL eneRgy. 29 aRmsteaD anD testeR, 1987; Dickson anD faneLLi, 2003; Dipippo, 2008. 30 ipcc, sRRen 2012. 31 gRant et aL., 1982. 32 hJaRtaRson anD einaRsson, 2010. 33 LunD anD boyD, 2009. 34 testeR et aL., 2006. 35 egRe anD miLewski, 2002. 36 (iRena-hyDRo 2015) hyDRopoweR – technoLogy bRief; iea-etsap anD iRena technoLogy bRief e06 – febRuaRy 2015. www.etsap.oRg – www.iRena.oRg; inteRnationaL RenewabLe eneRgy agency (iRena); eneRgy technoLogy systems anaLysis pRogRamme. 37 (ipcc-sRRen 2012), chapteR 6. 38 (khan et aL., 2009). 39 faLcao, 2009; khan anD bhuyan, 2009; us Doe, 2010. 40 faLcao et aL., 2000; faLcao, 2009. 41 faLcao, 2009. 42 faLcao, 2009. 43 khan anD bhuyan, 2009. 44 bosc, 1997. 45 anDRe, 1976; De LaLeu, 2009. 46 paik, 2008. 47 chaRLieR, 2003; etsap 2010b. 48 engineeRing business, 2003; tsb, 2010. 49 peyRaRD et aL. 2006. 50 vanZwieten et aL., 2005. 51 veneZia anD hoLt, 1995; Raye, 2001; vanZwieten et aL., 2005. 52 (gpi-en 2014) powe[R] 2030 -. a euRopean gRiD foR 3/4 RenewabLe eLectRicity by 2030; gReenpeace inteRnationaL / eneRgynautics; maRch 2014. 53 hvac cabLe systems aRe cuRRentLy Less attRactive as cabLe Losses aRe higheR anD tRansmission capacity is Less than with hvac oveRheaD Lines. 54 weiss, w. et aL. (2011): soLaR heat woRLDwiDe - maRkets anD contRibution to the eneRgy suppLy 2009. iea soLaR heating anD cooLing pRogRamme, may 2011. inteRnationaL eneRgy agency (iea), paRis, fRance. 55 weiss, w., et aL. (2008): pRocess heat coLLectoRs – state of the aRt. iea heating anD cooLing pRogRamme anD iea soLaRpaces pRogRamme, 2008. inteRnationaL eneRgy agency (iea), paRis, fRance. 56 tRavasaRos, c. (2011): the gReek soLaR theRmaL maRket anD inDustRiaL appLications oveRview of the maRket situation. gReek soLaR inDustRy association, woRLD sustainabLe eneRgy Days 2011, weLs, 3.3.2011, http://www.wseD.at/fiLeaDmin/ReDakteuRe/wseD/2011/DownLoaD_pResentations/tRavasaRos.p Df. 57 weiss, w. et aL. (2011): soLaR heat woRLDwiDe - maRkets anD contRibution to the eneRgy suppLy 2009. iea soLaR heating anD cooLing pRogRamme, may 2011. inteRnationaL eneRgy agency (iea), paRis, fRance. 58 weiss, w. et aL. (2011): soLaR heat woRLDwiDe - maRkets anD contRibution to the eneRgy suppLy 2009. iea soLaR heating anD cooLing pRogRamme, may 2011. inteRnationaL eneRgy agency (iea), paRis, fRance. 59 nitsch, J. et aL. (2010): LeitstuDie 2010 - LangfRistsZenaRien unD stRategien füR Den ausbau DeR eRneueRbaRen eneRgien in DeutschLanD bei beRücksichtigung DeR entwickLung in euRopa unD gLobaL. stuttgaRt, kasseL, teLtow, Deutsches ZentRum füR Luft- unD RaumfahRt, fRaunhofeR institut füR winDeneRgie unD eneRgiesystemtechnik (iwes), ingenieuRbüRo füR neue eneRgien (ifne). 60 JageR, D. et aL. (2011): financing RenewabLe eneRgy in the euRopean eneRgy maRket. bRusseLs, ecofys nL, fRaunhofeR isi, tu vienna eeg, eRnst &young, euRopean commission (Dg eneRgy). 61 weiss, w., et aL. 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69 iea (2011b): cogeneRation anD RenewabLes. inteRnationaL eneRgy agency (iea), paRis, fRance. 70 kaLtschmitt, m. et aL., eDs. (2009): eneRgie aus biomasse - gRunDLagen, techniken unD veRfahRen. beRLin, heiDeLbeRg, spRingeR. 71 kaLtschmitt, m. et aL., eDs. (2009): eneRgie aus biomasse - gRunDLagen, techniken unD veRfahRen. beRLin, heiDeLbeRg, spRingeR. 72 pehnt, m. et aL. (2007): biomasse unD effiZienZ - voRschLäge ZuR eRhÖhung DeR eneRgieeffiZienZ von §8 unD §7-anLagen im eRneueRbaRe-eneRgien-gesetZ. aRbeitspapieR nR. 1 im Rahmen Des pRoJektes “eneRgiebaLance – optimaLe systemLÖsungen füR eRneueRbaRe eneRgien unD eneRgieeffiZienZ”. heiDeLbeRg, institut füR eneRgie unD umweLtfoRschung heiDeLbeRg gmbh (ifeu). 73 iea (2007): RenewabLes foR heating anD cooLing. inteRnationaL eneRgy agency (iea), paRis, fRance. nitsch, J. et aL. (2010): LeitstuDie 2010 - LangfRistsZenaRien unD stRategien füR Den ausbau DeR eRneueRbaRen eneRgien in DeutschLanD bei beRücksichtigung DeR entwickLung in euRopa unD gLobaL. stuttgaRt, kasseL, teLtow, Deutsches ZentRum füR Luft- unD RaumfahRt, fRaunhofeR institut füR winDeneRgie unD eneRgiesystemtechnik (iwes), ingenieuRbüRo füR neue eneRgien (ifne). 74 DbfZ (2010): monitoRing ZuR wiRkung Des eRneueRbaRe-eneRgien-gesetZes (eeg) auf Die entwickLung DeR stRomeRZeugung aus biomasse (unveRÖffentLichteR entwuRf). LeipZig, Deutsches biomassefoRschungsZentRum. 75 gäRtneR, s. et aL. (2008): optimieRungen füR einen nachhaLtigen ausbau DeR biogaseRZeugung unD -nutZung in DeutschLanD, mateRiaLbanD e: ÖkobiLanZen. heiDeLbeRg, institut füR eneRgie- unD umweLtfoRschung. 76 (f-iws 2010) fRaunhofeR iws, eRneueRbaRes methan koppLung von stRom- unD gasnetZ m.sc. maReike Jentsch, DR. michaeL steRneR (iwes), DR. michaeL specht (Zsw), tu chemnitZ, speicheRwoRkshop chemnitZ, 28.10.2010. 77 (DLR-wagneR 2015) DR. ReR.nat. noRbeRt wagneR; http://www.DLR.De/tt/en/DesktopDefauLt.aspx/tabiD-7197/ 78 (iRena – stoRage 2015) RenewabLes anD eLectRicity stoRage – a technoLogy RoaDmap; inteRnationaL RenewabLe eneRgy agency (iRena) iRena innovation anD technoLogy centRe; RobeR t-schuman-pLatZ 3; 53175 bonn; geRmany; June 2015

hanD they incRease the use of RenewabLe eneRgy. the eneRgy savings achieveD by ReDucing the neeD of high gRaDe eneRgy wiLL be paRtLy compensateD by an incRease of RenewabLe eneRgy. 27 us epa (uniteD states enviRonmentaL pRotection agency) (2007) cooL Roofs. http://www.epa.gov/heatisLD/stRategies/cooLRoofs.htmL 28 aceee (ameRican counciL foR an eneRgy-efficient economy) (2007) consumeR guiDe to home eneRgy savings - cooLing eQuipment. http://www.aceee.oRg/consumeRguiDe/cooLing.htm#ReDuce chapter 12 1 2

3 4

5 6 7

8 9

10 chapter 11 1

2 3

4 5

13 6

7 8 9 10 11

14 15

16 17 18 19 20

21 22 23 24

25 26

(gRaus et aL. 2012); eneRgy DemanD pRoJections foR eneRgy [R]evoLution 2012; wina gRaus; kateRina keRmeLi; utRecht univeRsity, maRch 2012; commissioneD by: gReenpeace inteRnationaL anD DLR; http://www.eneRgybLuepRint.info/1432.0.htmL (iea weo 2014); woRLD eneRgy outLook 2014, inteRnationaL eneRgy agency. (DLR 2015); pRoJect RepoRt; aLteRnative tRanspoRt technoLogies foR megacities; geRman aeRospace centeR (DLR), institute of vehicLe concepts (DLR-fk), stuttgaRt, geRmany; 27 febRuaRy 2015. (iea 2014): inteRnationaL eneRgy agency (iea), paRis: eneRgy baLances of oecD countRies anD eneRgy baLances of non-oecD countRies, 2014 eDition. http://Data.iea.oRg iea (2007) eneRgy use in the new miLLennium – tRenDs in iea countRies. oecD/inteRnationaL eneRgy agency. ipcc (2007) fouRth assessment RepoRt. woRking gRoup iii: mitigation of cLimate change. cambRiDge univeRsity pRess. iea (2009) eneRgy technoLogy tRansitions foR inDustRy: stRategies foR the next inDustRiaL RevoLution. paRis, fRance: oecD/iea, 2009. (uniutRecht 2013); backgRounD mateRiaL about the eneRgy intensive inDustRies in the 30 % Debate; foR inteRnaL use within gReenpeace; wina gRaus (uu); miRJam haRmeLink (haRmeLink consuLting); Dian phyLipsen (phyLipsen cLimate change consuLting); maRiëLLe coRsten (uu); June 2013. (Reeep 2008) gLobaL status RepoRt on eneRgy efficiency 2008. (iea 2008a) woRLD tRenDs in eneRgy use anD efficiency – key insights fRom iea inDicatoR anaLysis, inteRnationaL eneRgy agency, paRis. (iea 2007). tRacking inDustRiaL eneRgy efficiency anD co2 emissions. inteRnationaL eneRgy agency, paRis, fRance. (iea etp 2015); eneRgy technoLogy peRspectives 2015 – tRacking cLean eneRgy pRocess; inteRnationaL eneRgy agency; June 2015. this is baseD on a numbeR of ZeRo-eneRgy DweLLing in the netheRLanDs anD geRmany, consuming 400-500 m3 natuRaL gas peR yeaR, with a fLooR suRface between 120 anD 150 m2. this ResuLts in 0.1 gJ/m2/yR anD is conveRteD by 3100 heating DegRee Days to 32 kJ/m2/hDD. wbcsD (woRLD business counciL on sustainabLe DeveLopment) (2005). pathways to 2050 – eneRgy anD cLimate change. iea (2006). eneRgy technoLogy peRspectives – scenaRios anD stRategies to 2050. oecD/iea, 2006. bettgenhäuseR, k., t. boeRmans anD s. schimschaR (2009) sectoRaL emission ReDuction potentiaLs anD economic costs foR cLimate change (seRpec-cc). ResiDentiaL buiLDings anD seRvice sectoR. ecofys, netheRLanDs. enviRohaRvest (2008) heat RecoveRy. http://www.enviRohaRvest.ca/heat_RecoveRy.htm bettgenhäuseR, k., t. boeRmans anD s. schimschaR (2009) sectoRaL emission ReDuction potentiaLs anD economic costs foR cLimate change (seRpec-cc). ResiDentiaL buiLDings anD seRvice sectoR. ecofys, netheRLanDs. Reeep (2009) impLementation of a Dissemination stRategy foR efficient cook stoves in noRtheast bRaZiL. (ehpa 2014) euRopean heat pump maRket anD statistics RepoRt – euRopean heat pump association. henDeL-bLackfoRD, s., t. angeLini, s. oZawa (2007) eneRgy efficiency in Life-styLes: euRope anD Japan. ecofys foR eu-Japan centRe foR inDustRiaL coopeRation. eneRgy staR (2008) compact fLuoRescent Light buLbs. http://www.eneRgystaR.gov/inDex.cfm?c=cfLs.pR_cfLs (usa-eneRgy-gov 2014) eneRgy.gov website (http://eneRgy.gov/eneRgysaveR/aRticLes/LeDLighting), u.s. DepaRtment of eneRgy, 1000 inDepenDence ave. sw washington Dc 20585 / usa; novembeR 2014. iea (2009b) gaDgets anD gigawatts. inteRnationaL eneRgy agency. paRis, fRance. iea (2003) cooL appLiances - poLicy stRategies foR eneRgy efficient homes. https://www.iea.oRg/textbase/nppDf/fRee/2000/cooL_appLiance2003.pDf bettgenhauseR et aL. (2009). us Doe eeRe (uniteD states DepaRtment of eneRgy; eneRgy efficiency anD RenewabLe eneRgy) (2008) inventions & innovation pRoJect fact sheet. high eneRgy efficiency aiR conDitioning. http://www1.eeRe.eneRgy.gov/inventions/pDfs/nimitZ.pDf DaRLing, D. (2005) soLaR cooLing. the encycLopeDia of aLteRnative eneRgy anD sustainabLe Living. http://www.DaviDDaRLing.info/encycLopeDia/s/ae_soLaR_cooLing.htmL austRian eneRgy agency, 2006 - note that soLaR cooLing anD geotheRmaL cooLing may ReDuce the neeD foR high gRaDe eneRgy such as natuRaL gas anD eLectRicity. on the otheR

310

13 14

15 16 17 18 19 20 21 22 23 24

25 26

27 28 29

(iea-weo sR 2015); woRLD eneRgy outLook – speciaL RepoRt 2015, inteRnationaL eneRgy agency; June 2015. DLR 2012: pRoJect RepoRt – tRanspoRt scenaRio buiLDing in the e[R] 2012. pagenkopf, J., schmiD, s., fRieske, b., geRman aeRospace centeR (DLR), institute of vehicLe concepts; stuttgaRt, geRmany. (DLR 2015); pRoJect RepoRt - aLteRnative tRanspoRt technoLogies foR megacities; geRman aeRospace centeR (DLR), institute of vehicLe concepts; stuttgaRt, geRmany. (eyRing et aL 2005) eyRing, v., kÖhLeR, h., LaueR, a., LempeR, b. (2005): emissions fRom inteRnationaL shipping: 2. impact of futuRe technoLogies on scenaRios untiL 2050, JouRnaL of geophysicaL ReseaRch, 110, D17305. (fuLton 2004); fuLton, L. anD eaDs, g. (2004): iea/smp moDeL Documentation anD RefeRence case pRoJection, pubLisheD by wbscD. (gReenpeace geRmany 2015): gReenpeace stRategy foR gReen mobiLity; D. moseR /gpD; gehL aRchitects DenmaRk 2015. gRunDitZ, e. a. (2014). bev poweRtRain component siZing with Respect to peRfoRmance, eneRgy consumption anD DRiving patteRns. DepaRtment of eneRgy anD enviRonment, chaLmeRs univeRsity of technoLogy Licentiate of engineeRing. Lienkamp, m. (2014). status of eLectRicaL mobiLity 2014 wagneR, R., n. pReschitschek, et aL. (2013). “cuRRent ReseaRch tRenDs anD pRospects among the vaRious mateRiaLs anD Designs useD in Lithium-baseD batteRies.” J appL eLectRochem 43: 481-496. sae off-highway engineeRing onLine (2013). “abb ‘fLash chaRges’ eLectRic bus in 15 s.” RetRieveD 20.01.2015, fRom http://aRticLes.sae.oRg/12293/. egvi (2014). “unpLuggeD - inDuctive chaRging foR eLectRic vehicLes (febRuaRy 2014).” RetRieveD 28.01.2015, fRom http://www.egvi.eu/pRoJects/13/38/unpLuggeD-inDuctivechaRging-foR-eLectRic-vehicLes-febRuaRy-2014. fta (2014b). Review anD evaLuation of wiReLess poweR tRansfeR (wpt) foR eLectRic tRansit appLications, fta RepoRt no. 0060, feDeRaL tRansit aDministRation. f. t. a. u.s. DepaRtment of tRanspoRtation. Li, J. L. f. (2013). “case stuDy of ev city bus opeRations.” fRom http://bestaR.LbL.gov/us-chinawoRkshop-2013/fiLes/2013/04/Jan-Li-Lithium-foRce.pDf. foRbes (2014). “tesLa’s batteRy swap stations wiLL heLp it ReQuaLify foR Zev cReDits in caLifoRnia.” RetRieveD 20.01.2015, fRom http://www.foRbes.com/sites/gReatspecuLations/2014/12/30/tesLas-batteRy-swap-stationswiLL-heLp-it-ReQuaLify-foR-Zev-cReDits-in-caLifoRnia/. Den boeR, e., s. aaRnik, et aL. (2013). ZeRo emissions tRucks - an oveRview of state-of-the-aRt technoLogies anD theiR potentiaL. DeLft, ce DeLft. eichLseDeR, h. anD m. kLeLL (2012). wasseRstoff in DeR fahRZeugtechnik, spRingeR. feRRaRi, c., s. offingeR, et aL. (2012). stuDie Zu Range extenDeR konZepten füR Den einsatZ in einem batteRieeLektRischen fahRZeug - RexeL. stuttgaRt, DLR-fk. accoRDing to (DLR 2012) foR the 2012 eDition of eneRgy [R]evoLution – the aDvanceD eneRgy [R]evoLution intRoDuces the same efficiency technoLogies fasteR. (tavassy 2011); tavassZy, L. anD van meiJeRen, J. (2011): moDaL shift taRget foR fReight tRanspoRt above 300 km: an assessment, Discussion papeR, 17th acea sag meeting. (nasa 2011) bRaDLey, m. anD DRoney, c. (2011): subsonic uLtRa gReen aiRcRaft ReseaRch: phase i finaL RepoRt, issueD by nasa. (akeRman 2005) akeRman, J. (2005): sustainabLe aiR tRanspoRt - on tRack in 2050. tRanspoRtation ReseaRch paRt D, 10, 111-126. (icao 2008): committee on aviation enviRonmentaL pRotection (caep), steeRing gRoup meeting, fesg caep/8 tRaffic anD fLeet foRecasts. tosca (2011): technoLogy oppoRtunities anD stRategies towaRD cLimate-fRienDLy tRanspoRt (RepoRts). (fuLton & eaDs 2004); fuLton, L. anD g. eaDs. (2004) iea/smp moDeL Documentation anD RefeRence case pRoJection. woRLD business counciL foR sustainabLe DeveLopment (wbcsD). http://www.wbcsD.oRg/web/pubLications/mobiLity/smp-moDeL-Document.pDf. (wbscD 2004) woRLD business counciL foR sustainabLe DeveLopment. (van Rompuy 2010); geeRts, s., veRweRft, b., vantoRRe, m. anD van Rompuy, f. (2010): impRoving the efficiency of smaLL inLanD vesseLs, pRoceeDings of the euRopean inLanD wateRway navigation confeRence. (icct 2012); icct (2011): ReDucing gReenhouse gas emissions fRom ships – cost effectiveness of avaiLabLe options. (eyRing et aL. 2005). (maRintek 2000); stuDy of gReenhouse emissions fRom ships, finaL RepoRt to the inteRnationaL maRitime oRganZiation.

energy

[r]evolution

13.2.1 definitiOn Of sectOrs

13.2 glOssary Of cOmmOnly used terms and abbreviatiOns

the definition of different sectors follows the sectorial break down of the iea world energy outlook series. all definitions below from IeA Key World energy Statistics.

term/unit/abbreviation

chp co2 gDp ppp iea J kJ mJ gJ pJ eJ w kw mw gw tw kwh twh t gt

combined heat and power carbon dioxide, the main greenhouse gas gross domestic product (means of assessing a country’s wealth) purchasing power parity (adjustment to gdp assessment to reflect comparable standard of living) international energy agency joule, a measure of energy kilojoule = 1,000 joules megajoule = 1 million joules gigajoule = 1 billion joules petajoule = 1015 joules exajoule = 1018 joules watt, measure of electrical capacity kilowatt = 1,000 watts megawatt = 1 million watts gigawatt = 1 billion watts terawatt = 1012 watts kilowatt-hour, measure of electrical output = 1,000 watt-hours terawatt-hour, or 1012 watt-hours tonnes, measure of weight gigatonnes = 1 billion tonnes

industry sector: consumption in the industry sector includes the following subsectors (energy used for transport by industry is not included -> see under “transport” • iron and steel industry • chemical industry • non-metallic mineral products e.g. glass, ceramic, cement etc. • transport equipment • machinery • mining • food and tobacco • paper, pulp and print • wood and wood products (other than pulp and paper) • construction • textile and Leather

transport sector: - fossil fuels 23.03 mj/kg 8.45 mj/kg 6.12 gj/barrel 38000.00 kj/m3

conversion factors coaL Lignite oiL gas

1 cubic 1 barrel 1 us gallon 1 uk gallon

0.0283 m3 159 liter 3.785 liter 4.546 liter

the transport sector includes all fuels from transport such as road, railway, aviation, domestic navigation. fuel used for ocean, coastal and inland fishing is included in “other sectors” other sectors:

- different energy units tJ gcal mtoe

conversion factors fRom: to:

mbtu

gwh

multiply by

238.8 2.388 x 10-5

947.8

0.2778

multiply by multiply by

tJ gcal mtoe mbtu gwh

1 4.1868 x 10-3

4.1868 x 104

107

1.0551 x 10-3

0.252

3.6

860

10(-7)

3.968 1.163 x 10-3

1 3968 x 107 2.52 x 10-8 8.6 x 10

-5

11630

1 2.931 x 10-4 3412

other sectors cover agriculture, forestry, fishing, residential, commercial and public services non-energy use: covers use of other petroleum products such as paraffin waxes, lubricants, bitumen etc.

311

world energy [r]evolution a sustainable world energy outlook

l i st o f f i g u r e s

figuRe

1.1

figuRe figuRe

1.2 1.3

figuRe figuRe

1.4 1.5

figuRe

3.1

figuRe figuRe figuRe figuRe

3.2 3.3 3.4 3.5

figuRe

3.6

figuRe figuRe

4.1 4.2

figuRe figuRe figuRe

4.3 4.4 4.5

figuRe

4.6

figuRe

4.7

figuRe

4.8

figuRe

5.1

figuRe

5.2

figuRe

5.3

figuRe

5.4

figuRe

5.5

figuRe

5.6

figuRe

5.7

figuRe

5.8

gLobaLy aveRageD combineD LanD anD ocean suRface tempeRatuRe anomaLy gLobaLy aveRageD sea LeveL change gLobaLy aveRageD gReenhouse gas concentRations gLobaLy anthRopogenic co 2 emissions wiDespReaD impacts attRibuteD to cLimate change baseD on the avaiLabLe scientific LiteRatuRe since the aR 4

estimateD RenewabLe eneRgy shaRe of gLobaL finaL eneRgy consumption 2013 a DecentRaLiseD eneRgy futuRe the evoLving appRoach to gRiDs the smaRt-gRiD vision foR the eneRgy [R]evoLution changing vaLue chain foR pLanning, constRuction anD opeRation of new poweR pLants aDD figuRe customeR stRuctuRe by voLtage LeveL

RetuRn chaRacteRistics of RenewabLe eneRgies oveRview Risk factoRs foR RenewabLe eneRgy pRoJects investment stages of RenewabLe eneRgy pRoJects key baRRieRs to Re investment gLobaL new investment in RenewabLe poweR anD fueLs , DeveLopeD anD DeveLoping countRies , 2004–2014 gLobaL new investment in RenewabLe poweR anD fueLs , by Region 2001-2014 investment categoRies – Definition by bLoombeRg new eneRgy finance 2015 gLobaL new investment in RenewabLe eneRgy by asset cLass , 2004–147

312

19 19 21

39 41 43 45 46 47 50 51 51 53 54 55 56 57

futuRe DeveLopment of investment costs foR RenewabLe eneRgy technoLogies 71 expecteD DeveLopment of eLectRicity geneRation costs fRom RenewabLe poweR geneRation in the eneRgy [ R ] evoLution scenaRios 71 gLobaL oiL pRoDuction 1950 – 2011 anD pRoJections untiL 2050 75 coaL scenaRio : base DecLine of 2% peR yeaR anD new pRoJects 75 winD poweR – shoRt teRm pRognosis vs ReaL DeveLopment – gLobaL cumuLative capacity 76 winD poweR – Long teRm maRket pRoJections untiL 2030 77 soLaR photovoLtaic – shoRt teRm pRognosis vs ReaL DeveLopment – gLobaL cumuLative capacity 79 soLaR photovoLtaic – Long teRm maRket pRoJections untiL 2030 80

gLobaL : finaL eneRgy intensity unDeR the RefeRence anD both eneRgy [R]evoLution scenaRios figuRe 6.1.2 gLobaL : pRoJection of totaL finaL eneRgy DemanD by sectoR – RefeRence , eneRgy [ R ] evoLution , aDvanceD eneRgy [ R ] evoLution scenaRios figuRe 6.1.3 gLobaL : DeveLopment of eLectRicity DemanD by sectoR in the eneRgy [R]evoLution scenaRios figuRe 6.1.4 gLobaL : DeveLopment of the finaL eneRgy DemanD foR tRanspoRt by sectoR in the eneRgy [ R ] evoLution scenaRios figuRe

19 19

6.1.1

84 85 85

figuRe

6.1.5

gLobaL : DeveLopment of finaL eneRgy DemanD foR heat by sectoR in the eneRgy [ R ] evoLution scenaRios 85 figuRe 6.1.6 gLobaL : DeveLopment of eLectRicity geneRation stRuctuRe – RefeRence , eneRgy [ R ] evoLution , aDvanceD eneRgy [ R ] evoLution scenaRios 85 figuRe 6.1.7 gLobaL : DeveLopment of totaL eLectRicity suppLy costs & of specific eLectRicity geneRation costs in the scenaRios 87 figuRe 6.1.8 gLobaL : investment shaRes - RefeRence veRsus eneRgy [ R ] evoLution scenaRios 87 figuRe 6.1.9 gLobaL : pRoJection of heat suppLy by eneRgy caRRieR – RefeRence , eneRgy [ R ] evoLution , aDvanceD eneRgy [ R ] evoLution scenaRios 88 figuRe 6.1.10 gLobaL : DeveLopment of investments foR RenewabLe heat geneRation technoLogies RefeRence , eneRgy [ R ] evoLution , aDvanceD eneRgy [ R ] evoLution scenaRios 89 figuRe 6.1.11 gLobaL : empLoyment in the eneRgy sectoR unDeR the RefeRence anD eneRgy [ R ] evoLution scenaRios 90 figuRe 6.1.12 gLobaL : gLobaL pRopoRtion of fossiL fueL anD RenewabLe empLoyment in 2015 anD 2030 90 figuRe 6.1.13 gLobaL : finaL eneRgy consumption in tRanspoRt unDeR the scenaRios 91 figuRe 6.1.14 gLobaL : pRoJection of totaL pRimaRy eneRgy DemanD ( peD ) by eneRgy caRRieR 92 figuRe 6.1.15 gLobaL : DeveLopment of co 2 emissions by sectoR unDeR the eneRgy [ R ] evoLution scenaRios 92 figuRes 6.2.1-6.2.13 oecD noRth ameRica 94-103 figuRes 6.3.1-6.3.13 Latin ameRica 104-113 figuRes 6.4.1-6.4.13 oecD euRope 114-123 figuRes 6.5.1-6.5.13 afRica 124-133 figuRes 6.6.1-6.6.13 miDDLe east 134-143 figuRes 6.7.1-6.7.13 easteRn euRope / euRasia 144-153 figuRes 6.8.1-6.8.13 inDia 154-163 figuRes 6.9.1-6.9.13 otheR asia 164-173 figuRes 6.10.1-6.10.13 china 174-183 figuRes 6.11.1-6.11.13 oecD asia oceania 184-193

figuRe

7.1

methoDoLogy oveRview

195

figuRe figuRe

8.1 8.2

205

figuRe figuRe figuRe figuRe

8.3 8.4 8.5 8.6

figuRe

8.7

figuRe

8.8

gLobaL annuaL poweR pLant maRket 1970 - 2014 gLobaL annuaL poweR pLant maRket – excLuDing china : 1970 - 2014 usa annuaL poweR pLant maRket: 1970 - 2014 eu annuaL poweR pLant maRket: 1970 - 2014 china annuaL poweR pLant maRket: 1970 - 2014 gLobaL anD RegionaL poweR pLant maRket shaRes 2004 - 2014 estimateD RenewabLe eneRgy shaRe of gLobaL eLectRicity pRoDuction , enD -2014 aveRage annuaL gRowth Rates of RenewabLe eneRgy capacity anD biofueLs pRoDuction , enD 2009–2014

figuRe

9.1

figuRe

9.2

gLobaLy aveRage combineD LanD anD ocean suRface tempeRatuRe anomaLy RenewabLe eneRgy potentiaL anaLysis

206 207 208 209 210 212 213 221 222

energy

[r]evolution

l i st o f f i g u r e s figuRe

figuRe figuRe figuRe figuRe

figuRe figuRe figuRe figuRe figuRe figuRe figuRe figuRe figuRe figuRe

figuRe figuRe figuRe figuRe figuRe figuRe figuRe figuRe figuRe

figuRe figuRe figuRe figuRe figuRe

figuRe figuRe

figuRe figuRe figuRe figuRe

10.1

continued

iLLustRative system foR eneRgy pRoDuction anD use iLLustRating the RoLe of Re aLong with otheR pRoDuction options 231 10.2 exampLe of the photovoLtaic effect 232 10.3 photovoLtaic technoLogy 232 10.4 DiffeRent configuRations of soLaR poweR systems 234 10.5 csp technoLogies : paRaboLic tRough , centRaL ReceiveR / soLaR toweR anD paRaboLic Dish 236 10.6 pRincipLe of csp systems 237 10.7 ewea eaRLy winD tuRbine Designs 238 10.8 basic component of winD tuRbines without geaRboxes 239 10.9 gRowth of siZe of typicaL commeRciaL winD tuRbines 239 10.10 offshoRe winD founDation technoLogies 240 10.11 biogas technoLogy 241 10.12 schematic view of commeRciaL bioeneRgy Routes 243 10.13 ghg emissions of bioeneRgy anD fossiL fueLs 244 10.14 scheme showing an enhanceD geotheRmaL system ( egs ) 246 10.15 schematic DiagRam of a geotheRmaL conDensing steam poweR pLant ( top ) anD a binaRy- cycLe poweR pLant ( bottom ) 246 10.16 Run - of - RiveR hyDRopoweR pLant 247 10.17 typicaL hyDRopoweR pLant with ReseRvoiR 248 10.18 typicaL pumpeD stoRage poweR pLant 248 10.19 typicaL in - stReam hyDRopoweR pLant 249 10.20 wave eneRgy: cLassification baseD on pRincipLes of opeRation 250 10.21 osciLLating wateR coLumns 251 10.22 osciLLating - boDy systems 251 10.23 oveRtopping Devices 251 10.24 cLassification of cuRRent tiDaL anD ocean eneRgy technoLogies ( pRincipLes of opeRation ) 252 10.25 twin tuRbine hoRiZontaL axis Device 253 10.26 veRticaL axis Device 253 10.27 cRoss fLow Device 253 10.28 compaRison of ac anD Dc investment costs using oveRheaD Lines 258 10.29 compaRison of the ReQuiReD numbeR of paRaLLeL pyLons anD space to tRansfeR 10 gw of eLectRic capacity 259 10.30 natuRaL fLow systems vs . foRceD ciRcuLation systems 260 10.31 two main types of DistRict heating systems : top, open Loop ( singLe pipe system ), bottom , cLoseD Loop ( DoubLe pipe system ) 263 10.32 exampLes foR heat pump systems 265 10.33 oveRview stoRage capacity of DiffeRent eneRgy stoRage systems 268 10.34 RenewabLe (poweR) (to) methane - RenewabLe gas 269 10.35 potentiaL Locations anD appLications of eLectRicity stoRage in the poweR system 269

figuRe figuRe figuRe figuRe figuRe figuRe figuRe figuRe figuRe figuRe figuRe figuRe

figuRe figuRe figuRe figuRe

figuRe

11.1

finaL eneRgy DemanD foR the woRLD by sub sectoR anD fueL souRce in 2012 272 11.2 bReakDown of finaL eneRgy consumption in 2012 by sub sectoR foR inDustRy 272 11.3 bReakDown of eLectRicity use in otheR sectoRs in 2012 273 11.4 bReakDown of finaL eneRgy DemanD in 2012 foR eLectRicity anD fueLs/heat in otheR sectoRs 273 11.5 bReakDown of fueL anD heat use in otheR sectoRs in 2012 273 11.6 bReakDown of eLectRicity use by sub sectoR in otheR sectoRs in 2012 274 11.7 finaL eneRgy DemanD in the RefeRence scenaRio peR sectoR woRLDwiDe 274 11.8 finaL eneRgy DemanD in the RefeRence scenaRio peR Region 275 11.9 finaL eneRgy DemanD peR capita in the RefeRence scenaRio 275 11.10 eneRgy DemanD in inDustRy in the RefeRence scenaRio peR Region 275 11.11 eneRgy DemanD in otheR sectoRs in the RefeRence scenaRio peR Region 276 11.12 shaRe eLectRicity anD fueL consumption by otheR sectoRs in totaL finaL eneRgy DemanD in 2012 anD 2050 in the RefeRence scenaRio 276 11.13 eneRgy efficiency inDex foR iRon anD steeL inDustRy pRimaRy eneRgy use peR capita 277 11.14 specific eneRgy consumption in ammonia ( nh 3) pRoDuction in 1995 anD 2005 278 11.15 eLements of new buiLDing Design that can substantiaLLy ReDuce eneRgy use 280 11.16 gLobaL finaL eneRgy use in the peRioD 20122050 in inDustRy in the eneRgy [ R ] evoLution anD the RefeRence DemanD scenaRio DistinguisheD by eLectRicity anD fueLs / heat 282 11.17 finaL eneRgy use in sectoR inDustRy in the eneRgy [ R ] evoLution anD the RefeRence DemanD scenaRio DistinguisheD by woRLD Regions 283 11.18 gLobaL finaL eneRgy use in the peRioD 2012-2050 in otheR sectoRs in the eneRgy [ R ] evoLution anD the RefeRence scenaRio DistinguisheD by eLectRicity anD fueLs / heat 283 11.19 finaL eneRgy use in otheR sectoRs in the eneRgy [ R ] evoLution anD the RefeRence scenaRio DistinguisheD by woRLD Regions 284 11.20 aveRage gLobaL eneRgy intensities in tRanspoRt – finaL eneRgy peR $ gDp in the eneRgy 285 [ R ] evoLution anD the RefeRence scenaRio 11.21 aveRage gLobaL eneRgy intensities in inDustRy – eLectRicity anD fueLs / heat DemanD peR $ gDp in the eneRgy [ R ] evoLution anD the RefeRence scenaRio 285 11.22 aveRage gLobaL eneRgy intensities in otheR sectoRs – eLectRicity anD fueLs / heat DemanD peR capita in the eneRgy [ R ] evoLution anD the RefeRence scenaRio 285 11.23 aveRage gLobaL eneRgy intensities peR woRLD Region – finaL eneRgy peR capita in the eneRgy [ R ] evoLution scenaRio 285

313

world energy [r]evolution a sustainable world energy outlook

l i st o f f i g u r e s figuRe figuRe figuRe figuRe figuRe

figuRe

figuRe figuRe figuRe

figuRe

figuRe figuRe figuRe

figuRe

figuRe figuRe

figuRe

314

12.1

continued

woRLD finaL eneRgy use peR tRanspoRt moDe 2012 – 2050 – RefeRence scenaRio 288 12.2 woRLD finaL eneRgy use by Region 2012 – 2050 – RefeRence scenaRio 289 12.3 schematic aRchitectuRe of batteRy eLectRic vehicLes ( bev ) 290 12.4 schematic aRchitectuRe of fueL ceLL eLectRic vehicLes ( fcev ) 292 12.5 woRLD aveRage ( stock - weighteD ) passengeR tRanspoRt eneRgy intensities foR toDay anD 2050 294 12.6 woRLD aveRage ( stock - weighteD ) fReight tRanspoRt eneRgy intensities foR toDay anD 2050 294 12.7 DeveLopment of tonne - km oveR time in the RefeRence scenaRio 295 12.8 eneRgy intensities ( mJ / p - km ) foR aiR tRanspoRt in eneRgy [ R ] evoLution scenaRios 296 12.9 DeveLopment of finaL eneRgy use foR aviation by technoLogies in the RefeRence anD both eneRgy [ R ] evoLution scenaRios 296 12.10 DeveLopment of finaL eneRgy use foR RaiL tRanspoRt by technoLogies in the RefeRence anD both eneRgy [ R ] evoLution scenaRios 297 12.11 DeveLopment of finaL eneRgy use foR maRine tRanspoRt by technoLogies in the RefeRence anD both eneRgy [ R ] evoLution scenaRios 299 12.12 eneRgy intensities foR LDv cuRRentLy anD unDeR the eneRgy [ R ] evoLution in 2050 300 12.13 LDv occupancy Rates cuRRentLy anD unDeR the eneRgy [ R ] evoLution in 2050 301 12.14 oveRview eLectRicity DemanD of tRanspoRt technoLogies peR 100 passengeR kiLometeRs 301 12.15 saLes shaRe of conventionaL ice , autonomous hybRiD anD gRiD - connectabLe vehicLes in 2050 303 12.16 assumeD vehicLe saLes by segment cuRRentLy anD 2050 unDeR the eneRgy [ R ] evoLution 303 12.17 DeveLopment of the aveRage annuaL LDv kiLometRes DRiven peR woRLD Region unDeR the eneRgy [ R ] evoLution 304 12.18 DeveLopment of finaL eneRgy use foR RoaD tRanspoRt by technoLogies in the RefeRence anD both eneRgy [ R ] evoLution scenaRios 305 12.19 woRLD finaL eneRgy use by Region 2012 – 2050 – eneRgy [ R ] evoLution scenaRios 306

energy

[r]evolution

l i st o f ta b l e s tabLe

4.1

tabLe

4.2

tabLe tabLe tabLe

5.1 5.2 5.3

tabLe

5.4

tabLe

5.5

tabLe tabLe tabLe tabLe tabLe tabLe tabLe tabLe

5.6 5.7 5.8 5.9 5.10 5.11 5.12 5.13

tabLe

5.14

tabLe

5.15

tabLe

5.16

tabLe

tabLe tabLe tabLe

tabLe

tabLe tabLe tabLe tabLe tabLe tabLe

how Does the cuRRent RenewabLe maRket woRk in pRactice ? categoRisation of baRRieRs to RenewabLe eneRgy investment

eneRgy

woRLD Regions useD in the scenaRios popuLation DeveLopment pRoJections gDp DeveLopment pRoJections aveRage annuaL gRowth Rates DeveLopment pRoJections foR fossiL fueL anD biomass pRices in $2010 DeveLopment of efficiency anD investment costs foR seLecteD new poweR pLant technoLogies ; exempLaRy Data foR oecD euRope photovoLtaics ( pv ) cost assumptions csp cost assumptions winD cost assumptions biomass cost assumptions geotheRmaL poweR cost assumptions ocean eneRgy cost assumptions hyDRo poweR cost assumptions oveRview of expecteD investment anD opeRation & maintenance costs pathways foR heating technoLogies in euRope assumptions foR hyDRogen anD synfueL pRoDuction assumeD aveRage gRowth Rates anD annuaL maRket voLumes by RenewabLe technoLogy oveRview of key paRameteRs of the iLLustRative scenaRios baseD on assumptions that aRe exogenous to the moDeLs Respective enDogenous moDeL ResuLts

6.1.1 gLobaL :

52 62 65 65 66 67 68 69 69 70 70 70 71 73 73 74

pRoJection of RenewabLe eLectRicity geneRation capacity unDeR the RefeRence anD the eneRgy [ R ] evoLution scenaRios 86 6.1.2 gLobaL : pRoJection of RenewabLe heat suppLy unDeR the RefeRence anD both eneRgy [ R ] evoLution scenaRios in pJ / a 88 6.1.3 gLobaL : instaLLeD capacities foR RenewabLe heat geneRation unDeR the scenaRios in gw 89 6.1.4 gLobaL : totaL empLoyment in the eneRgy sectoR in miLLion Jobs 90 6.1.5 gLobaL : pRoJection of tRanspoRt eneRgy DemanD by moDe in the RefeRence anD the eneRgy [ R ] evoLution scenaRios in pJ / a 91 6.1.6 gLobaL : accumuLateD investment costs foR eLectRicity geneRation anD fueL cost savings unDeR the eneRgy [ R ] evoLution scenaRio compaReD to the RefeRence scenaRio 93 6.1.7 gLobaL : accumuLateD investment costs foR RenewabLe heat geneRation unDeR the eneRgy [ R ] evoLution scenaRio compaReD to the RefeRence scenaRio 93 6.1.8 gLobaL : accumuLateD investment costs foR eLectRicity geneRation anD fueL cost savings unDeR the aDvanceD eneRgy [ R ] evoLution scenaRio compaReD to the RefeRence scenaRio 93 6.1.9 gLobaL : accumuLateD investment costs foR RenewabLe heat geneRation unDeR the aDvanceD eneRgy [ R ] evoLution scenaRio compaReD to the RefeRence scenaRio 93 6.2.1-6.2.13 oecD noRth ameRica 94-103 6.3.1-6.3.13 Latin ameRica 104-113 6.4.1-6.4.13 oecD euRope 114-123 6.5.1-6.5.13 afRica 124-133 6.6.1-6.6.13 miDDLe east 134-143 6.7.1-6.7.13 easteRn euRope / euRasia 144-153

tabLe tabLe tabLe tabLe

6.8.1-6.8.13 inDia 6.9.1-6.9.13 otheR asia 6.10.1-6.10.13 china 6.11.1-6.11.13 oecD asia

tabLe

7.1

tabLe

7.2

tabLe tabLe

7.3 74

tabLe tabLe tabLe tabLe

7.5 7.6 7.7 7.8

tabLe

7.9

tabLe

7.10

tabLe tabLe

7.11 7.12

tabLe

7.13

summaRy of empLoyment factoRs useD in gLobaL anaLysis 2015 196 empLoyment factoRs useD foR coaL fueL suppLy ( mining anD associateD Jobs ) 197 RegionaL muLtipLieRs 197 fossiL fueLs anD nucLeaR eneRgy: capacity anD DiRect Jobs 199 winDpoweR: capacity anD DiRect Jobs 200 biomass: capacity anD DiRect Jobs 200 geotheRmaL: capacity anD DiRect Jobs 201 wave anD tiDaL poweR : capacity anD DiRect Jobs 201 soLaR photovoLtaics : capacity anD DiRect Jobs 202 soLaR theRmaL poweR : capacity anD DiRect Jobs 202 soLaR heating : capacity anD DiRect Jobs 203 geotheRmaL anD heat pump heating : capacity anD DiRect Jobs 203 biomass heat: DiRect Jobs in fueL suppLy 203

tabLe

8.1

gLobaL anD RegionaL poweR pLant maRket shaRes

tabLe

9.1

tabLe

9.2

tabLe

9.3

tabLe tabLe

9.4 9.5

fossiL anD uRanium ReseRves , ResouRces anD occuRRences potentiaL emissions as a conseQuence of the fossiL ReseRves anD ResouRces assumptions on fossiL fueL use in the eneRgy [ R ] evoLution scenaRio RenewabLe eneRgy potentiaL RenewabLe enegy fLows , potentiaL anD utiLiZation in eJ of inputs pRoviDeD by natuRe

tabLe

10.1

tabLe

10.2

tabLe

11.1

tabLe

11.2

tabLe tabLe

12.1 12.2

tabLe

12.3

tabLe

12.4

tabLe

12.5

tabLe

12.6

tabLe

12.7

tabLes

oceania

typicaL type anD siZe of appLications peR maRket segment oveRview of the thRee main tRansmission soLutions eneRgy efficiency of chemicaL anD petRochemicaL inDustRy eneRgy efficiency inDex of puLp anD papeR pRoDuction

154-163 164-173 174-183 184-193

215 216 218 220 220 233 258 278 279

seLection of measuRes anD inDicatoRs 289 oveRheaD catenaRy anD thiRD RaiL systems in uRban pubLic tRanspoRt appLications 291 aiR tRaffic substitution potentiaL of high speeD RaiL ( hsR ) 294 the woRLD aveRage eneRgy intensities foR mDv anD hDv cuRRentLy anD 2050 eneRgy [ R ] evoLution scenaRio 298 technicaL efficiency potentiaL foR woRLD passengeR tRanspoRt 301 technicaL efficiency potentiaL foR woRLD fReight tRanspoRt 301 seLecteD paRameteRs foR vehicLe technoLogies foR city appLications 302

13.1.1-13.11.24

ResuLts Data tabLes

316-359

315

g lo b a l : r e f e r e n c e s c e n a r i o table 13.1.4: global: installed capacity gw

table 13.1.1 global: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share

2012 19,125 5,477 1,718 3,876 0 889 147 2,450 205 3,672 521 19 97 69 5 0 3,478 1,670 193 1,351 0 88 175 2 0

2020 24,639 7,315 1,897 4,614 0 647 158 3,215 523 4,458 1,254 69 408 111 34 3 3,854 1,873 187 1,510 0 63 218 2 1

2025 28,392 8,702 2,044 5,665 0 532 180 3,443 652 4,832 1,608 123 519 148 60 6 3,983 1,929 185 1,577 0 50 237 3 1

2030 32,169 10,167 2,143 6,710 0 418 202 3,670 780 5,207 1,962 189 630 185 85 10 4,088 1,956 182 1,650 0 36 259 3 1

2040 39,767 13,224 2,380 9,020 0 301 234 3,856 1,009 5,862 2,552 346 832 283 173 41 4,240 1,958 175 1,785 0 26 290 4 1

2050 45,752 15,074 2,617 10,759 0 212 256 4,054 1,251 6,431 3,202 521 1,096 419 303 76 4,359 1,891 171 1,941 0 23 326 6 1

1,576 1,903 22,604 15,409 7,148 1,911 5,226 978 147 2,450 0 0 4,744 3,672 521 97 379 70 5 0 1,839 1,910 0 0 18,863 618 3% 21%

1,632 2,222 28,492 18,266 9,189 2,085 6,124 710 158 3,215 1 0 7,010 4,458 1,254 408 740 113 34 3 2,371 2,161 3 0 23,969 1,665 6% 25%

1,633 2,349 32,374 20,865 10,631 2,229 7,242 582 180 3,443 1 0 8,066 4,832 1,608 519 890 151 60 6 2,751 2,328 3 0 27,304 2,133 7% 25%

1,631 2,457 36,256 23,464 12,123 2,325 8,360 454 202 3,670 1 0 9,121 5,207 1,962 630 1,039 188 85 10 3,130 2,495 4 0 30,639 2,602 7% 25%

1,628 2,612 44,007 29,104 15,182 2,556 10,806 327 234 3,856 1 0 11,046 5,862 2,552 832 1,299 287 173 41 3,922 2,835 4 0 37,255 3,425 8% 25%

1,641 2,717 50,110 32,945 16,966 2,787 12,700 236 256 4,054 1 0 13,111 6,431 3,202 1,096 1,577 425 303 76 4,615 2,878 4 0 42,622 4,374 9% 26%

table 13.1.2 global: final energy consumption in transport pj/a 2012 2020 2025 road 78,688 89,912 98,701 fossil fuels 74,800 84,096 91,476 biofuels 2,486 3,622 4,487 synfuels 0 0 0 natural gas 1,394 2,095 2,472 hydrogen 0 0 0 electricity 9 99 267 rail 2,766 3,134 3,335 fossil fuels 1,701 1,839 1,952 biofuels 0 0 0 synfuels 0 0 0 electricity 1,065 1,294 1,383 navigation 2,173 2,506 2,707 fossil fuels 2,173 2,506 2,707 biofuels 0 0 0 synfuels 0 0 0 aviation 4,120 5,026 5,512 fossil fuels 4,120 5,026 5,512 biofuels 0 0 0 synfuels 0 0 0 total (incl. pipelines) 90,119 103,044 112,778 fossil fuels 82,794 93,468 101,647 biofuels (incl. biogas) 2,486 3,622 4,487 synfuels 0 0 0 natural gas 3,765 4,561 4,994 hydrogen 0 0 0 electricity 1,074 1,393 1,650 total res 2,711 3,964 4,898 res share 3% 4% 4%

2030 107,510 98,864 5,352 0 2,850 0 444 3,517 2,054 0 0 1,463 2,963 2,963 0 0 5,943 5,943 0 0 122,511 109,825 5,352 0 5,427 0 1,907 5,832 5%

2040 120,944 108,461 7,224 0 4,319 0 939 3,887 2,256 0 0 1,631 3,269 3,269 0 0 6,730 6,730 0 0 137,518 120,716 7,224 0 7,008 0 2,570 7,869 6%

2050 130,313 114,616 7,982 0 6,218 0 1,497 4,260 2,452 0 0 1,808 3,470 3,470 0 0 7,573 7,573 0 0 148,418 128,112 7,982 0 9,020 0 3,304 8,846 6%

table 13.1.3 global: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 8,275 8,030 239 0 6 10,083 9,566 507 10 0 129,751 91,517 26,739 803 0 468 10,224 0 148,109 109,112 27,486 804 16 468 10,224 0 21%

2020 9,035 8,713 309 1 13 11,280 10,557 704 15 4 149,371 107,600 28,805 1,385 0 661 10,921 0 169,687 126,869 29,818 1,386 28 661 10,921 4 20%

2025 9,538 9,173 348 1 16 11,876 11,030 823 19 5 159,100 115,232 29,945 1,745 0 775 11,404 0 180,515 135,434 31,115 1,746 35 775 11,404 5 20%

2030 10,053 9,638 393 2 20 12,498 11,502 969 23 5 169,071 123,061 31,105 2,105 0 886 11,914 0 191,622 144,200 32,467 2,107 43 886 11,914 5 20%

2040 10,456 9,945 477 5 28 13,876 12,519 1,320 31 6 188,257 137,389 33,793 2,840 0 1,217 13,018 0 212,588 159,853 35,590 2,845 59 1,217 13,018 6 20%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

316

2050 10,732 10,139 548 11 34 16,079 13,893 2,139 40 6 205,512 149,826 36,299 3,830 0 1,646 13,911 0 232,322 173,858 38,986 3,841 74 1,646 13,911 6 21%

total generation fossil hard coal (& non-renewable waste) lignite gas (w/o h2) oil diesel nuclear hydrogen (fuel cells, gas power plants, gas chp) renewables hydro wind of which wind offshore pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy fluctuating res (pv, wind, ocean) share of fluctuating res res share

2012 5,680 3,712 1,407 373 1,499 378 55 393 0 1,575 1,099 277 5 97 87 11 3 0 375 7% 28%

table 13.1.5: global: final energy demand pj/a 2012 total (incl. non-energy use) 360,650 total energy use1 326,859 transport 90,119 oil products 82,794 natural gas 3,765 biofuels 2,486 synfuels 0 electricity 1,074 RES electricity 225 hydrogen 0 res share transport 3% industry 106,313 electricity 28,747 RES electricity 6,034 public district heat 5,446 RES district heat 113 hard coal & lignite 25,402 oil products 12,939 gas 26,305 solar 13 biomass 7,441 geothermal 20 hydrogen 0 res share industry 13% other sectors 130,428 electricity 38,088 RES electricity 7,994 public district heat 6,555 RES district heat 136 hard coal & lignite 5,718 oil products 17,894 gas 24,960 solar 790 biomass 36,126 geothermal 297 hydrogen 0 res share other sectors 35% total res 61,675 res share 19% non energy use 33,791 oil 24,430 gas 7,735 coal 1,625

2020 7,343 4,500 1,820 387 1,918 308 66 447 0 2,396 1,331 554 20 332 150 17 11 1 887 12% 33%

2020 418,349 379,586 103,044 93,468 4,561 3,622 0 1,393 343 0 4% 129,641 37,294 9,176 6,052 307 32,795 14,200 29,915 70 9,290 24 0 15% 146,901 47,601 11,712 6,709 340 5,878 18,409 29,178 1,314 37,374 437 0 35% 74,010 19% 38,763 27,189 9,499 2,075

2025 8,237 5,016 2,092 408 2,178 264 73 471 0 2,749 1,438 681 36 413 174 22 19 2 1,096 13% 33%

2025 451,812 410,576 112,778 101,647 4,994 4,487 0 1,650 411 0 4% 140,466 41,992 10,462 6,263 348 33,324 14,512 33,643 106 10,600 27 0 15% 157,332 54,653 13,617 6,969 388 5,977 18,663 31,634 1,639 37,275 521 0 34% 79,880 19% 41,237 28,234 10,683 2,320

2030 9,130 5,532 2,373 422 2,439 216 83 496 0 3,101 1,544 807 55 494 199 28 26 4 1,305 14% 34%

2030 485,226 441,590 122,511 109,825 5,427 5,352 0 1,907 480 0 5% 151,290 46,689 11,746 6,473 394 34,396 14,824 36,828 141 11,909 29 0 16% 167,789 61,705 15,524 7,229 440 6,076 18,940 34,091 1,964 37,177 605 0 33% 85,762 19% 43,636 29,263 11,818 2,555

2040 10,747 6,534 2,888 453 2,930 161 102 517 0 3,696 1,715 998 98 635 243 42 49 15 1,647 15% 34%

2040 541,973 495,388 137,518 120,716 7,008 7,224 0 2,570 645 0 6% 170,465 55,149 13,843 6,496 456 35,528 14,989 43,349 272 14,647 37 0 17% 187,404 76,400 19,178 7,711 541 5,954 19,301 38,538 2,568 36,076 856 0 32% 96,342 19% 46,585 30,036 13,760 2,790

2050 12,033 7,134 3,091 484 3,341 112 105 544 0 4,355 1,878 1,217 145 803 293 62 74 28 2,048 17% 36%

2050 587,701 538,502 148,418 128,112 9,020 7,982 0 3,304 865 0 6% 186,496 62,870 16,449 6,446 508 36,033 14,585 48,889 470 17,158 45 0 19% 203,589 87,266 22,832 8,285 654 5,903 19,849 43,036 3,359 34,701 1,189 0 31% 106,213 20% 49,199 30,424 15,822 2,953

1 excluding heat produced by chp autoproducers

table 13.1.6: global: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (20,938 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 9,522 5,063 1,902 1,760 621 175 2,717 1,579 251 807 79 12,238 6,643 2,154 2,567 875

2020 11,492 6,722 1,976 2,073 534 186 2,937 1,832 243 810 52 14,428 8,553 2,219 2,884 772

2025 12,968 7,824 2,074 2,430 432 209 2,917 1,836 240 802 39 15,885 9,660 2,313 3,232 680

2030 14,468 8,978 2,125 2,800 332 232 2,889 1,826 236 801 26 17,356 10,804 2,361 3,601 591

2040 17,838 11,393 2,283 3,669 233 262 2,828 1,780 226 805 17 20,667 13,173 2,509 4,474 511

2050 19,724 12,582 2,432 4,272 158 280 2,787 1,723 219 831 14 22,511 14,305 2,651 5,103 452

794 541 30,469 146% 6,167 3,224 6,165 10,765 4,148 7,080 4.3

790 506 34,247 164% 7,404 3,509 6,995 12,679 3,660 7,717 4.4

761 491 36,801 176% 7,710 3,674 7,623 14,110 3,683 8,083 4.6

740 479 39,362 188% 8,025 3,843 8,251 15,563 3,680 8,425 4.7

710 470 44,332 212% 8,522 4,113 9,147 18,862 3,688 9,039 4.9

683 449 47,532 227% 8,856 4,406 9,794 20,694 3,782 9,551 5.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.1.7: global: primary energy demand pj/a 2012 total 534,873 fossil 434,330 hard coal (& non-renewable waste) 132,625 lignite 21,617 natural gas 118,747 crude oil 161,342 nuclear 26,884 renewables 73,659 hydro 13,222 wind 1,874 solar 1,223 biomass (& renewable waste) 54,893 geothermal 2,445 ocean energy 2 of which non-energy use 33,791 total res 73,665 res share 14%

2020 619,779 491,672 161,539 22,197 131,936 176,000 35,098 93,009 16,049 4,514 2,979 65,783 3,674 10 38,763 93,020 15%

2025 666,706 527,749 175,300 23,086 145,473 183,891 37,576 101,380 17,398 5,789 3,829 70,087 4,253 23 41,237 101,391 15%

2030 714,904 565,057 190,051 23,536 159,631 191,839 40,054 109,792 18,747 7,065 4,681 74,351 4,913 36 43,636 109,803 15%

2040 802,761 634,952 215,125 24,926 193,201 201,700 42,074 125,734 21,106 9,189 6,464 82,137 6,692 146 46,585 125,743 16%

2050 859,954 676,182 224,542 26,224 217,258 208,159 44,241 139,531 23,154 11,529 8,879 86,749 8,945 275 49,199 139,540 16%

energy

g lo b a l : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.1.10: global: installed capacity gw

table 13.1.8 global: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 Renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share

2012 19,125 5,477 1,718 3,876 0 889 147 2,450 205 3,672 521 19 97 69 5 1 3,478 1,670 193 1,351 0 88 175 2 0

2020 23,246 6,330 1,419 4,912 0 575 111 1,872 510 4,349 1,932 126 942 166 97 31 4,046 1,773 155 1,602 0 58 427 24 7

2025 25,397 5,830 842 4,972 0 404 73 1,345 555 4,513 3,848 473 2,123 365 428 101 4,620 1,615 82 1,907 0 25 876 97 16

2030 28,497 4,745 338 4,807 0 166 51 559 580 4,613 6,278 1,098 3,844 664 1,601 251 5,134 1,328 22 2,156 2 8 1,335 252 32

2040 37,019 2,357 99 3,550 28 33 15 182 606 4,773 11,291 2,831 7,054 1,385 4,844 831 5,818 562 0 2,270 56 3 2,043 813 126

2050 43,831 468 0 1,288 69 9 5 0 620 4,937 14,938 4,008 9,914 2,032 8,138 1,482 6,021 126 0 1,921 281 1 2,419 1,253 300

1,576 1,903 22,604 15,409 7,148 1,911 5,226 978 147 2,450 0 0 4,744 3,672 521 97 379 70 5 1 1,839 1,910 0 0 18,863 618 3% 21%

1,738 2,308 27,292 16,936 8,104 1,574 6,514 633 111 1,872 7 2 8,478 4,349 1,932 942 937 190 97 31 2,246 2,050 36 0 22,980 2,904 11% 31%

1,956 2,663 30,016 15,752 7,446 925 6,879 429 73 1,345 16 7 12,904 4,513 3,848 2,123 1,430 462 428 101 2,430 2,098 245 0 25,268 6,071 20% 43%

2,171 2,963 33,631 13,619 6,074 360 6,960 174 51 559 34 20 19,419 4,613 6,278 3,844 1,915 916 1,601 251 2,622 2,058 983 0 27,973 10,373 31% 58%

2,385 3,433 42,837 8,805 2,919 99 5,736 36 15 182 211 166 33,640 4,773 11,291 7,054 2,649 2,198 4,844 831 2,965 1,826 4,237 0 33,816 19,176 45% 79%

2,327 3,694 49,852 3,469 594 0 2,859 11 5 0 650 604 45,733 4,937 14,938 9,914 3,039 3,286 8,138 1,482 3,211 1,315 8,330 0 37,004 26,334 53% 93%

table 13.1.9 global: final energy consumption in transport pj/a 2012 2020 2025 road 78,688 83,781 82,443 fossil fuels 74,800 77,617 72,348 biofuels 2,486 3,759 4,945 synfuels 0 0 0 natural gas 1,394 1,981 2,498 hydrogen 0 18 367 electricity 9 406 2,284 rail 2,766 3,110 3,231 fossil fuels 1,701 1,662 1,461 biofuels 0 67 129 synfuels 0 0 0 electricity 1,065 1,381 1,640 navigation 2,173 2,492 2,615 fossil fuels 2,173 2,442 2,485 biofuels 0 49 130 synfuels 0 0 0 aviation 4,120 4,683 4,767 fossil fuels 4,120 4,678 4,621 biofuels 0 4 146 synfuels 0 0 0 total (incl. pipelines) 90,119 96,169 94,941 fossil fuels 82,794 86,400 80,915 biofuels (incl. biogas) 2,486 3,880 5,351 synfuels 0 0 0 natural gas 3,765 4,074 4,352 hydrogen 0 18 367 electricity 1,074 1,797 3,956 total res 2,711 4,444 7,210 res share 3% 5% 8%

2030 79,473 62,387 6,126 0 2,864 1,990 6,106 3,338 1,142 252 0 1,945 2,728 2,447 281 0 4,712 4,335 377 0 91,918 70,311 7,035 0 4,464 1,990 8,117 12,877 14%

2040 67,361 32,730 6,588 0 3,044 8,190 16,810 3,631 697 267 0 2,667 2,849 2,151 698 0 4,667 3,638 1,030 0 79,738 39,216 8,583 0 4,043 8,190 19,706 30,598 38%

2050 57,356 12,138 5,829 0 2,724 13,521 23,144 3,751 274 164 0 3,314 2,860 1,589 1,271 0 5,004 2,946 2,058 0 69,735 16,947 9,322 0 2,960 13,521 26,985 46,972 67%

table 13.1.10 global: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

[r]evolution

2012 8,275 8,030 239 0 6 10,083 9,566 507 10 0 129,751 91,517 26,739 803 0 468 10,224 0 148,109 109,112 27,486 804 16 468 10,224 0 21%

2020 8,580 7,855 622 56 47 12,720 10,950 1,537 187 46 141,519 95,693 29,247 2,620 421 1,477 12,062 0 162,819 114,499 31,406 2,675 655 1,477 12,062 46 25%

2025 9,343 7,008 1,311 686 338 15,517 11,165 3,437 799 116 140,142 85,672 30,159 6,296 810 3,249 13,909 47 165,002 103,844 34,907 6,982 1,948 3,249 13,909 163 33%

2030 9,658 5,946 1,852 1,170 689 18,605 10,821 5,485 2,067 232 137,770 72,665 29,281 11,814 1,329 6,332 16,216 133 166,032 89,431 36,619 12,984 4,085 6,332 16,216 366 42%

2040 10,355 2,466 2,768 2,963 2,158 25,629 8,729 9,132 6,703 1,064 127,812 40,425 26,603 22,742 2,462 13,289 21,494 797 163,796 51,620 38,504 25,704 11,323 13,289 21,494 1,862 66%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2050 9,738 430 2,384 3,917 3,006 31,685 5,871 12,459 10,328 3,025 115,170 13,432 23,718 27,461 3,389 18,041 26,134 2,995 156,593 19,734 38,562 31,378 16,723 18,041 26,134 6,021 86%

2012 5,680 3,712 1,407 373 1,499 378 55 393 0 1,575 1,099 277 5 97 87 11 3 0 375 7% 28%

table 13.1.12: global: final energy demand pj/a 2012 total (incl. non-energy use) 360,650 total energy use1 326,859 transport 90,119 oil products 82,794 natural gas 3,765 biofuels 2,486 synfuels 0 electricity 1,074 RES electricity 225 hydrogen 0 res share transport 3% industry 106,313 electricity 28,747 RES electricity 6,034 public district heat 5,446 RES district heat 220 hard coal & lignite 25,402 oil products 12,939 gas 26,305 solar 13 biomass 7,441 geothermal 20 hydrogen 0 res share industry 13% other sectors 130,428 electricity 38,088 RES electricity 7,994 public district heat 6,555 RES district heat 265 hard coal & lignite 5,718 oil products 17,894 gas 24,960 solar 790 biomass 36,126 geothermal 297 hydrogen 0 res share other sectors 35% total res 61,910 res share 19% non energy use 33,791 oil 24,430 gas 7,735 coal 1,625

2020 7,492 4,098 1,612 292 1,863 284 47 260 2 3,132 1,316 820 37 732 194 28 31 11 1,563 21% 42%

2020 392,643 356,213 96,169 86,400 4,074 3,880 0 1,797 558 18 5% 122,283 36,525 11,349 5,989 741 28,584 11,564 28,191 710 9,966 754 0 19% 137,762 44,408 13,798 6,860 849 4,926 15,749 27,097 1,910 36,115 697 0 39% 81,333 23% 36,430 24,948 8,271 3,211

2025 9,148 3,902 1,474 171 2,018 203 35 184 4 5,058 1,365 1,573 142 1,603 284 69 126 37 3,214 35% 55%

2025 391,235 354,466 94,941 80,915 4,352 5,351 0 3,956 1,702 367 8% 122,458 39,464 16,974 6,511 1,872 24,724 8,530 28,654 2,066 10,976 1,478 54 27% 137,068 47,544 20,450 8,125 2,335 3,213 11,997 25,597 4,231 34,733 1,628 0 46% 103,976 29% 36,769 23,344 8,533 4,891

2030 11,521 3,662 1,305 69 2,164 96 28 76 9 7,774 1,397 2,510 326 2,839 392 137 405 95 5,444 47% 67%

2040 16,112 3,089 743 21 2,285 28 12 25 64 12,934 1,445 4,316 814 4,988 558 325 984 318 9,622 60% 80%

2030 384,295 347,228 91,918 70,311 4,464 7,035 0 8,117 4,692 1,990 14% 120,769 42,319 24,460 6,853 2,908 19,246 5,536 28,064 4,440 11,315 2,842 154 38% 134,542 50,268 29,054 9,181 3,896 1,487 9,108 22,594 7,374 31,510 3,019 0 56% 133,785 39% 37,066 22,006 8,699 6,362

2040 355,240 319,112 79,738 39,216 4,043 8,583 0 19,706 15,552 8,190 38% 110,931 46,866 36,986 7,082 5,135 6,362 2,028 21,649 9,313 10,866 5,862 904 62% 128,443 55,165 43,535 11,450 8,302 272 3,656 12,819 13,429 25,305 6,347 0 75% 196,390 62% 36,128 18,455 8,569 9,105

2050 19,469 2,140 264 0 1,861 10 5 0 250 17,079 1,503 5,575 1,131 6,745 746 485 1,473 552 12,871 66% 88%

2050 323,128 288,506 69,735 16,947 2,960 9,322 0 26,985 25,083 13,521 67% 98,343 48,360 44,951 6,896 6,167 633 304 9,260 10,747 11,173 7,792 3,177 85% 120,428 57,853 53,774 12,049 10,775 55 379 5,462 16,713 18,788 9,127 0 91% 239,934 83% 34,623 15,131 8,233 11,259

1 excluding heat produced by chp autoproducers

table 13.1.13: global: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (20,938 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 9,522 5,063 1,902 1,760 621 175 2,717 1,579 251 807 79 12,238 6,643 2,154 2,567 875

2020 10,105 5,849 1,483 2,178 465 130 2,820 1,724 203 847 47 12,925 7,572 1,685 3,025 642

2025 8,630 5,256 874 2,099 322 80 2,594 1,522 108 945 19 11,224 6,778 982 3,044 421

2030 6,714 4,192 360 1,977 132 54 2,268 1,214 30 1,019 5 8,982 5,406 389 2,996 191

2040 3,604 2,035 106 1,425 25 14 1,473 487 0 983 2 5,077 2,522 106 2,408 41

2050 887 391 0 484 7 5 808 110 0 697 1 1,695 501 0 1,182 13

794 541 30,469 146% 6,167 3,224 6,165 10,765 4,148 7,080 4.3

763 474 30,758 147% 6,689 3,116 6,474 11,210 3,270 7,717 4.04

713 374 26,923 129% 6,073 2,612 6,096 9,562 2,580 8,083 3.3

660 267 22,110 106% 5,154 2,095 5,334 7,471 2,055 8,425 2.6

577 119 12,014 57% 2,881 1,062 3,055 4,052 964 9,039 1.3

489 34 4,358 21% 1,131 379 1,391 1,111 347 9,551 0.5

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.1.14: global: primary energy demand pj/a 2012 total 534,873 fossil 434,330 hard coal (& non-renewable waste) 132,625 lignite 21,617 natural gas 118,747 crude oil 161,342 nuclear 26,884 renewables 73,659 hydro 13,222 wind 1,874 solar 1,223 biomass (& renewable waste) 54,893 geothermal 2,445 ocean energy 2 of which non-energy use 33,791 total res 73,665 res share 14%

2020 571,876 449,305 144,445 16,902 129,643 158,314 20,433 102,138 15,660 6,956 6,416 66,305 6,692 111 36,430 102,161 18%

2025 556,465 407,400 129,574 9,841 128,942 139,042 14,679 134,386 16,248 13,855 16,164 73,285 14,473 362 36,769 134,404 24%

2030 532,061 349,012 103,954 3,974 125,232 115,852 6,102 176,947 16,607 22,605 32,589 77,426 26,816 904 37,066 176,562 33%

2040 484,670 214,819 49,446 992 97,858 66,523 1,983 267,868 17,184 40,654 68,542 79,597 58,900 2,992 36,128 267,523 55%

2050 433,275 101,890 17,680 0 50,419 33,791 0 331,385 17,774 53,786 96,369 76,320 81,802 5,335 34,623 330,923 76%

317

g lo b a l : a d va n c e d e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.1.18: global: installed capacity gw

table 13.1.15 global: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 Renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share

2012 19,125 5,477 1,718 3,876 0 889 147 2,450 205 3,672 521 19 97 69 5 1 3,478 1,670 193 1,351 0 88 175 2 0

2020 23,540 6,182 1,419 4,872 0 585 111 1,872 552 4,349 2,158 180 1,090 186 131 32 4,046 1,773 155 1,602 0 58 427 24 7

2025 26,677 5,445 842 4,920 21 401 76 1,345 630 4,519 4,645 682 2,659 460 608 128 4,620 1,615 82 1,907 10 25 876 97 16

2030 31,733 4,016 338 4,719 53 153 54 559 658 4,621 7,737 1,623 5,067 897 2,552 363 5,134 1,328 22 2,155 38 8 1,335 252 33

2040 46,121 992 99 3,185 381 29 16 182 683 4,779 15,480 4,425 9,442 2,106 7,988 1,141 5,818 557 0 2,251 308 3 2,051 817 138

2050 61,524 0 0 1,358 1,358 0 0 0 701 4,966 21,673 6,330 13,613 3,167 14,035 2,010 6,011 0 0 1,728 1,728 0 2,492 1,380 411

1,576 1,903 22,604 15,409 7,148 1,911 5,226 978 147 2,450 0 0 4,744 3,672 521 97 379 70 5 1 1,839 1,910 0 0 18,863 618 3% 21%

1,738 2,308 27,586 16,757 7,955 1,574 6,474 643 111 1,872 7 2 8,950 4,349 2,158 1,090 979 210 131 32 2,246 2,050 98 51 23,161 3,281 12% 32%

1,956 2,663 31,297 15,284 7,061 925 6,796 426 76 1,345 48 22 14,621 4,519 4,645 2,659 1,505 558 608 128 2,430 2,098 812 70 25,912 7,432 24% 47%

2,171 2,963 36,867 12,703 5,344 360 6,783 161 54 559 123 79 23,482 4,621 7,737 5,067 1,993 1,149 2,552 363 2,622 2,058 2,176 328 29,689 13,167 36% 64%

2,385 3,433 51,939 6,443 1,549 99 4,746 32 16 182 828 721 44,487 4,779 15,480 9,442 2,734 2,923 7,988 1,141 3,069 1,776 8,403 1,851 36,847 26,063 50% 87%

2,327 3,684 67,535 0 0 0 0 0 0 0 3,497 3,497 64,037 4,966 21,673 13,613 3,193 4,547 14,035 2,010 3,318 1,230 19,317 3,514 40,163 37,296 55% 100%

table 13.1.16 global: final energy consumption in transport pj/a 2012 2020 2025 road 78,688 82,653 78,457 fossil fuels 74,800 76,151 66,806 biofuels 2,486 3,659 4,742 synfuels 0 67 91 natural gas 1,394 1,922 2,080 hydrogen 0 169 1,305 electricity 9 751 3,524 rail 2,766 3,278 3,922 fossil fuels 1,701 1,557 1,256 biofuels 0 47 103 synfuels 0 1 2 electricity 1,065 1,673 2,561 navigation 2,492 2,615 2,173 fossil fuels 2,173 2,451 2,554 biofuels 0 40 60 synfuels 0 1 1 aviation 4,636 4,635 4,120 fossil fuels 4,120 4,615 4,548 biofuels 0 21 85 synfuels 0 0 2 total (incl. pipelines) 90,119 95,181 91,510 fossil fuels 82,794 84,774 75,165 biofuels (incl. biogas) 2,486 3,767 4,990 synfuels 0 69 95 natural gas 3,765 3,964 3,797 hydrogen 0 169 1,305 electricity 1,074 2,438 6,158 total res 2,711 4,635 8,526 res share 3% 5% 9%

2030 71,706 52,751 5,190 388 1,788 3,773 8,204 4,718 881 152 11 3,674 2,698 2,323 349 26 4,423 3,826 555 42 85,457 59,782 6,247 467 3,161 3,773 12,027 16,643 19%

2040 51,475 16,057 5,451 1,988 645 11,228 18,095 6,774 340 175 64 6,196 2,739 1,703 759 277 3,885 2,452 1,050 383 67,846 20,552 7,436 2,711 1,142 11,228 24,778 41,135 61%

2050 38,750 0 3,996 2,737 0 14,039 20,715 8,356 0 130 89 8,138 2,700 0 1,603 1,098 3,602 0 2,138 1,464 56,534 0 7,866 5,387 0 14,039 29,242 56,533 100%

table 13.1.17 global: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 8,275 8,030 239 0 6 10,083 9,566 507 10 0 129,751 91,517 26,739 803 0 468 10,224 0 148,109 109,112 27,486 804 16 468 10,224 0 21%

2020 8,571 7,847 621 56 47 12,729 10,957 1,537 188 46 141,520 95,694 29,246 2,620 421 1,477 12,062 0 162,819 114,498 31,404 2,676 657 1,477 12,062 46 25%

2025 9,339 7,008 1,308 685 338 15,526 11,136 3,444 799 147 140,137 85,379 30,158 6,309 810 3,249 14,003 228 165,002 103,523 34,909 6,994 1,948 3,249 14,003 375 33%

2030 9,650 5,946 1,847 1,168 689 18,624 10,712 5,497 2,068 348 137,759 71,879 29,279 11,826 1,329 6,332 16,477 638 166,033 88,536 36,623 12,994 4,085 6,332 16,477 986 43%

2040 10,330 2,463 2,758 2,954 2,155 25,701 7,849 9,177 6,735 1,939 127,765 35,740 26,593 22,947 2,505 13,623 22,674 3,683 163,795 46,052 38,527 25,901 11,395 13,623 22,674 5,622 70%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

318

2050 9,287 0 2,330 3,823 3,134 32,842 0 12,859 11,407 8,576 114,433 10,150 24,198 28,624 3,579 18,707 29,176 0 156,563 10,150 39,386 32,446 18,121 18,707 29,176 8,576 94%

2012 5,680 3,712 1,407 373 1,499 378 55 393 0 1,575 1,099 277 5 97 87 11 3 0 375 7% 28%

table 13.1.19: global: final energy demand pj/a 2012 total (incl. non-energy use) 360,650 total energy use1 326,859 transport 90,119 oil products 82,794 natural gas 3,765 biofuels 2,486 synfuels 0 electricity 1,074 RES electricity 225 hydrogen 0 res share transport 3% industry 106,313 electricity 28,747 RES electricity 6,034 public district heat 5,446 RES district heat 220 hard coal & lignite 25,402 oil products 12,939 gas 26,305 solar 13 biomass 7,441 geothermal 20 hydrogen 0 res share industry 13% other sectors 130,428 electricity 38,088 RES electricity 7,994 public district heat 6,555 RES district heat 265 hard coal & lignite 5,718 oil products 17,894 gas 24,960 solar 790 biomass 36,126 geothermal 297 hydrogen 0 res share other sectors 35% total res 61,910 res share 19% non energy use 33,791 oil 24,430 gas 7,735 coal 1,625

2020 7,645 4,035 1,586 291 1,821 289 47 260 2 3,348 1,316 904 51 844 200 31 42 11 1,760 23% 44%

2020 391,662 355,232 95,181 84,774 3,964 3,767 69 2,438 791 169 5% 122,283 36,525 11,854 5,989 741 28,584 11,564 28,191 710 9,966 754 0 20% 137,769 44,417 14,415 6,859 849 4,927 15,746 27,097 1,910 36,115 697 0 39% 82,646 23% 36,430 24,948 8,271 3,211

2025 9,873 3,831 1,399 172 2,021 202 36 184 14 5,844 1,368 1,873 201 2,000 295 85 177 46 3,919 40% 59%

2025 387,812 351,043 91,510 75,165 3,797 4,990 95 6,158 2,881 1,305 9% 122,441 39,576 18,517 6,511 1,876 24,724 8,530 28,456 2,066 10,976 1,478 124 29% 137,092 47,561 22,253 8,129 2,341 3,234 11,989 25,442 4,243 34,732 1,628 135 48% 108,759 31% 36,769 23,344 8,533 4,891

2030 13,146 3,500 1,136 70 2,172 93 30 76 37 9,532 1,402 3,064 480 3,725 405 171 635 131 6,919 53% 73%

2040 19,951 2,491 377 21 2,054 24 15 25 330 17,105 1,457 5,892 1,271 6,678 579 452 1,616 432 13,001 65% 86%

2030 379,271 342,204 85,457 59,782 3,161 6,247 467 12,027 7,686 3,773 19% 121,143 43,008 27,486 6,852 2,925 19,241 5,425 27,636 4,440 11,315 2,842 382 41% 135,605 51,885 33,158 9,188 3,922 1,437 8,833 22,016 7,386 31,508 3,019 334 58% 145,102 42% 37,066 22,006 8,699 6,362

2040 346,573 310,445 67,846 20,552 1,142 7,436 2,711 24,778 21,567 11,228 61% 111,788 48,877 42,542 7,076 5,225 6,292 1,844 18,914 9,339 10,858 5,953 2,634 68% 130,811 59,177 51,507 11,447 8,452 234 3,168 9,935 13,608 25,309 6,544 1,390 82% 223,973 72% 36,128 18,286 8,569 9,274

2050 25,835 0 0 0 0 0 0 0 2,220 23,614 1,536 8,040 1,781 9,295 742 708 2,555 738 18,074 70% 91%

2050 313,575 278,953 56,534 0 0 7,866 5,387 29,242 29,242 14,039 100% 98,630 52,409 52,408 6,787 6,787 0 0 0 11,791 11,302 8,004 8,338 100% 123,788 63,763 63,762 11,919 11,919 0 0 0 16,833 19,322 9,606 2,346 100% 278,949 100% 34,623 14,744 8,233 11,646

1 excluding heat produced by chp autoproducers

table 13.1.20 global: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (20,938 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 9,522 5,063 1,902 1,760 621 175 2,717 1,579 251 807 79 12,238 6,643 2,154 2,567 875

2020 9,963 5,719 1,483 2,159 472 130 2,820 1,724 203 847 47 12,783 7,443 1,685 3,006 648

2025 8,260 4,918 874 2,065 319 84 2,589 1,522 108 940 19 10,849 6,440 982 3,006 422

2030 6,005 3,549 360 1,918 120 58 2,251 1,214 30 1,002 5 8,256 4,764 389 2,920 184

2040 2,134 855 106 1,136 22 15 1,347 482 0 862 2 3,480 1,337 106 1,998 39

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

794 541 30,469 146% 6,167 3,224 6,165 10,765 4,148 7,080 4.3

763 463 30,416 145% 6,689 3,116 6,350 11,068 3,193 7,717 3.9

710 347 25,947 124% 6,061 2,605 5,649 9,189 2,443 8,083 3.2

650 224 20,046 96% 5,117 2,038 4,499 6,751 1,640 8,425 2.4

540 67 8,086 39% 2,635 858 1,552 2,538 502 9,039 0.9

0 0 0 0% 0 0 0 0 0 9,551 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.1.21: global: primary energy demand pj/a 2012 total 534,873 fossil 434,330 hard coal (& non-renewable waste) 132,625 lignite 21,617 natural gas 118,747 crude oil 161,342 nuclear 26,884 renewables 73,659 hydro 13,222 wind 1,874 solar 1,223 biomass (& renewable waste) 54,893 geothermal 2,445 ocean energy 2 of which non-energy use 33,791 total res 73,665 res share 14%

2020 568,443 443,645 139,248 16,902 130,859 156,636 20,433 104,365 15,660 7,771 7,072 66,499 7,246 117 36,430 104,389 18%

2025 549,517 392,356 119,843 9,841 129,840 132,832 14,679 142,481 16,270 16,724 18,755 73,471 16,799 462 36,769 142,499 26%

2030 522,977 321,535 88,907 3,974 124,606 104,049 6,102 195,340 16,636 27,857 40,427 77,057 32,058 1,305 37,066 194,781 37%

2040 482,191 161,576 32,495 992 82,188 45,901 1,983 318,632 17,206 55,738 88,654 79,261 73,666 4,108 36,128 318,156 66%

2050 453,117 35,114 11,655 0 8,715 14,744 0 418,003 17,880 78,038 131,989 77,439 105,422 7,235 34,623 417,386 92%

energy

g lo b a l : i n v e st m e n t a n d e m p loy m e n t table 13.1.22: global: investments in electricity generation unit 201220212031ref 2020 2030 2040 fossil (w/o chp) billion $ 1,673.6 2,205.0 2,725.4 nuclear billion $ 678.6 740.5 654.9 chp (fossil + renewable) billion $ 712.2 651.8 433.5 renewables (w/o chp) billion $ 2,417.8 2,274.4 2,863.0 total billion $ 5,482.3 5,871.7 6,676.8 conventional (fossil & nuclear) billion $ 2,996.6 3,512.9 3,753.8 renewables billion $ 2,485.7 2,358.8 2,922.9 biomass billion $ 209.1 229.3 281.1 hydro billion $ 999.9 984.4 900.9 wind billion $ 585.5 690.7 973.4 pv billion $ 516.5 253.5 454.5 geothermal billion $ 113.4 111.4 132.0 solar thermal power plants billion $ 56.2 76.9 139.9 ocean energy billion $ 4.9 12.5 41.1 e[r] fossil (w/o chp) billion $ 1,248.5 544.4 819.7 nuclear billion $ 197.6 0.6 0.8 chp (fossil + renewable) billion $ 851.2 1,362.8 1,490.5 renewables (w/o chp) billion $ 3,808.8 9,872.1 12,385.8 total billion $ 6,106.1 11,779.9 14696.7 conventional (fossil & nuclear) billion $ 2,072.6 1,066.4 1,147.0 renewables billion $ 4,033.5 10,713.5 13,549.8 biomass billion $ 341.0 659.3 747.5 hydro billion $ 963.8 643.0 567.1 wind billion $ 1,068.3 3,361.5 4,437.7 pv billion $ 1,212.8 2,812.9 2,914.4 geothermal billion $ 214.5 898.8 1,299.3 solar thermal power plants billion $ 168.7 1,921.2 2,796.6 ocean energy billion $ 64.3 416.8 787.1 adv e[r] fossil (w/o chp) billion $ 1,167.4 496.0 938.5 nuclear billion $ 197.6 0.6 0.8 chp (fossil + renewable) billion $ 851.9 1,359.0 1,467.1 renewables (w/o chp) billion $ 4,292.3 13,403.0 18,094.0 total billion $ 6,509.1 15,258.6 20,500.3 conventional (fossil & nuclear) billion $ 1,981.0 1,016.8 1,250.2 renewables billion $ 4,528.1 14,241.8 19,250.1 biomass billion $ 364.0 673.6 773.7 hydro billion $ 963.8 657.3 588.7 wind billion $ 1,243.5 4,341.0 6,518.9 pv billion $ 1,402.1 3,826.3 3,845.3 geothermal billion $ 256.5 1,136.0 1,822.3 solar thermal power plants billion $ 230.3 3,019.3 4,654.6 ocean energy billion $ 67.9 588.3 1,046.7

20412050 2,866.8 731.1 123.8 2,775.8 6,497.6 3,680.7 2,816.9 265.3 895.3 1,011.5 281.4 157.5 174.3 31.6

2012unit 2050 9,470.9 billion $/a 2,805.1 billion $/a 1,921.3 billion $/a 10,331.0 billion $/a 24,528.3 billion $/a 13,944.1 billion $/a 10,584.3 billion $/a 984.8 billion $/a 3,780.5 billion $/a 3,261.1 billion $/a 1,505.9 billion $/a 514.2 billion $/a 447.5 billion $/a 90.2 billion $/a

annual average

858.0 0.0 1,675.0 13,170.0 15,703.0 1,019.4 14,683.7 1,136.2 608.8 5,176.3 3,045.8 1,280.3 2,818.1 618.1

3,470.6 billion $/a 198.9 billion $/a 5,379.5 billion $/a 39,236.7 billion $/a 48,285.8 billion $/a 5,305.3 billion $/a 42,980.4 billion $/a 2,884.0 billion $/a 2,782.7 billion $/a 14,043.8 billion $/a 9,986.0 billion $/a 3,692.9 billion $/a 7,704.7 billion $/a 1,886.4 billion $/a

89.0 5.1 137.9 1,006.1 1,238.1 136.0 1,102.1 73.9 71.4 360.1 256.1 94.7 197.6 48.4

1,069.2 0.0 1,619.6 19,835.9 22,524.7 1,194.9 21,329.9 1,036.2 668.8 7,549.4 4,333.3 1,856.6 5,071.2 814.4

3,671.1 billion $/a 198.9 billion $/a 5,297.6 billion $/a 55,625.2 billion $/a 64,792.8 billion $/a 5,443.0 billion $/a 59,349.8 billion $/a 2,847.5 billion $/a 2,878.7 billion $/a 19,652.8 billion $/a 13,406.9 billion $/a 5,071.3 billion $/a 12,975.3 billion $/a 2,517.3 billion $/a

94.1 5.1 135.8 1,426.3 1,661.4 139.6 1,521.8 73.0 73.8 503.9 343.8 130.0 332.7 64.5

2012-2050 242.8 71.9 49.3 264.9 628.9 357.5 271.4 25.3 96.9 83.6 38.6 13.2 11.5 2.3

[r]evolution

table 13.1.23: global: investments in renewable unit 2012ref 2020 heat pumps billion $ 131.7 deep geothermal billion $ 6.2 solar thermal billion $ 119.2 biomass billion $ 1,034.4 total billion $ 1,291.5 e[r] heat pumps billion $ 332.5 deep geothermal billion $ 122.9 solar thermal billion $ 401.2 bomass billion $ 893.7 total billion $ 1,750.3 adv e[r] heat pumps billion $ 332.5 deep geothermal billion $ 123.0 solar thermal billion $ 401.3 biomass billion $ 893.6 total billion $ 1,750.3

heat generation 202120312030 2040 134.3 169.9 0.5 10.1 145.2 216.1 912.8 427.9 1,192.8 824.0

20412050 184.6 6.1 251.4 391.7 833.8

2012unit 2050 620.5 billion $/a 22.9 billion $/a 731.8 billion $/a 2,766.9 billion $/a 4,142.1 billion $/a

annual average

1,325.4 252.4 1,778.8 403.7 3,760.4

1,951.0 1,133.5 2,258.7 269.5 5,612.6

2,282.9 5,891.9 billion $/a 1,003.7 2,512.5 billion $/a 1,749.4 6,188.1 billion $/a 164.1 1,731.0 billion $/a 5,200.2 16,323.4 billion $/a

151.1 64.4 158.7 44.4 418.5

1,325.4 252.4 1,782.2 403.5 3,763.5

2,040.8 1,139.7 2,304.6 268.6 5,753.7

2,393.0 6,091.7 billion $/a 1,123.1 2,638.2 billion $/a 1,819.0 6,307.2 billion $/a 130.3 1,695.9 billion $/a 5,465.4 16,733.0 billion $/a

156.2 67.6 161.7 43.5 429.1

table 13.1.24: global: total employment in the energy sector

million jobs adv e [ r ] scenariO

reference scenariO

by fuel coal gas, oil & diesel nuclear renewable total jobs by sector construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export total jobs (million) by technology coal gas, oil & diesel nuclear biomass hydro wind pv geothermal power solar thermal power ocean solar - heat geothermal & heat pump total jobs (million)

2012-2050 15.9 0.6 18.8 70.9 106.2

2015 9.76 3.58 0.73 14.62 28.69

2020 9.67 4.16 0.86 15.41 30.11

2025 8.63 4.56 0.83 15.59 29.62

2030 7.70 4.67 0.74 14.84 27.95

2020 4.80 4.00 0.52 26.91 36.24

2025 3.28 4.18 0.52 38.68 46.65

2030 1.97 3.98 0.51 41.56 48.01

4.86 2.38 3.23 17.76 0.47 28.69

5.09 2.44 3.94 18.12 0.52 30.11

4.60 2.23 4.30 17.93 0.54 29.62

3.95 1.91 4.27 17.27 0.57 27.95

8.32 5.49 4.82 17.27 0.34 36.24

14.59 8.87 6.96 15.97 0.26 46.65

15.56 9.58 9.00 13.67 0.20 48.01

9.76 3.58 0.73 10.97 1.45 0.70 1.01 0.03 0.03 0.00 0.36 0.07 28.7

9.67 4.16 0.86 11.85 1.46 0.72 0.87 0.03 0.04 0.00 0.37 0.05 30.1

8.63 4.56 0.83 12.05 1.47 0.76 0.84 0.03 0.05 0.00 0.34 0.04 29.6

7.70 4.67 0.74 11.76 1.29 0.65 0.66 0.03 0.08 0.01 0.31 0.04 28.0

4.80 4.00 0.52 12.07 1.01 4.22 6.69 0.18 0.45 0.23 1.59 0.48 36.2

3.28 4.18 0.52 12.55 0.83 6.91 11.04 0.30 1.66 0.45 3.94 0.99 46.7

1.97 3.98 0.51 11.54 0.71 8.18 10.32 0.39 2.66 0.65 5.64 1.46 48.0

319

o e c d n o r t h a m e r i ca : r e f e r e n c e s c e n a r i o table 13.2.1 Oecd north america: electricity generation twh/a 2012 2020 4,856 5,460 768 908 941 1,011 1,234 1,316 0 0 75 45 9 10 905 951 42 89 691 730 157 295 0 6 9 56 24 36 1 14 0 0 347 334 42 39 5 3 254 249 0 0 12 7 34 35 0 0 0 0

power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share (domestic generation)

194 153 5,203 3,340 810 946 1,487 87 9 905 0 0 958 691 157 9 76 24 1 0 358 382 0 0 4,459 166 3% 18%

182 153 5,794 3,588 947 1,014 1,565 52 10 951 0 0 1,255 730 295 56 124 36 14 0 406 384 0 0 5,001 351 6% 22%

2025 5,800 909 1,095 1,450 0 36 10 954 109 748 349 11 79 43 21 1 311 32 3 233 0 6 36 0 0

2030 6,140 967 1,121 1,584 0 26 9 957 129 765 403 17 101 49 28 2 287 26 2 217 0 5 37 0 0

2040 6,891 1,089 1,180 1,952 0 16 8 937 165 798 501 42 145 58 37 5 250 19 2 189 0 2 38 0 0

2050 7,649 1,132 1,259 2,367 0 8 6 935 202 806 605 74 201 69 47 12 221 8 2 169 0 1 41 0 0

157 154 6,111 3,773 941 1,098 1,683 42 10 954 0 0 1,384 748 349 79 145 43 21 1 433 391 0 0 5,284 428 7% 23%

133 155 6,428 3,957 993 1,123 1,801 31 9 957 0 0 1,514 765 403 101 166 49 28 2 459 399 0 0 5,567 506 8% 24%

93 157 7,141 4,457 1,108 1,182 2,141 17 8 937 0 0 1,748 798 501 145 204 58 37 5 519 416 0 0 6,204 651 9% 24%

63 159 7,871 4,952 1,139 1,261 2,537 9 6 935 0 0 1,984 806 605 201 243 69 47 12 582 416 0 0 6,870 818 10% 25%

table 13.2.2 Oecd north america: final energy consumption in transport pj/a 2012 2020 2025 2030 road 25,564 26,133 26,090 26,039 fossil fuels 24,388 24,509 24,065 23,615 biofuels 1,139 1,499 1,793 2,086 synfuels 0 0 0 0 natural gas 32 105 193 281 hydrogen 0 0 0 0 electricity 5 19 38 58 rail 663 696 723 749 fossil fuels 624 658 682 705 biofuels 0 0 0 0 synfuels 0 0 0 0 electricity 39 39 41 44 navigation 550 571 589 602 fossil fuels 550 571 589 602 biofuels 0 0 0 0 synfuels 0 0 0 0 aviation 2,161 2,253 2,307 2,372 fossil fuels 2,161 2,253 2,307 2,372 biofuels 0 0 0 0 synfuels 0 0 0 0 total (incl. pipelines) 29,748 30,504 30,579 30,654 fossil fuels 27,723 27,992 27,643 27,294 biofuels (incl. biogas) 1,139 1,499 1,793 2,086 synfuels 0 0 0 0 natural gas 842 956 1,064 1,173 hydrogen 0 0 0 0 electricity 44 58 80 101 total res 1,147 1,512 1,811 2,110 res share 4% 5% 6% 7% table 13.2.3 Oecd north america: heat supply pj/a 2012 0 0 0 0 0 867 779 88 0 0 19,082 15,798 1,697 68 0 14 1,506 0 19,949 16,577 1,784 68 0 14 1,506 0 11%

district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2020 48 46 2 0 0 865 771 94 0 0 20,914 17,333 1,920 125 0 14 1,522 0 21,827 18,149 2,016 125 0 14 1,522 0 11%

2025 61 59 2 0 0 839 736 103 0 0 21,471 17,619 2,069 199 0 14 1,571 0 22,371 18,414 2,174 199 0 14 1,571 0 12%

2030 72 69 4 0 0 820 704 117 0 0 22,031 17,911 2,217 272 0 14 1,616 0 22,924 18,684 2,338 272 0 14 1,616 0 13%

2040 26,275 22,425 2,857 0 848 0 144 804 757 0 0 47 630 630 0 0 2,529 2,529 0 0 31,170 26,341 2,857 0 1,781 0 191 2,904 9%

2040 82 77 5 0 0 830 665 165 0 0 23,247 18,343 2,736 474 0 15 1,680 0 24,159 19,085 2,905 474 0 15 1,680 0 16%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

320

2050 26,487 21,421 3,154 0 1,631 0 280 877 827 0 0 50 657 657 0 0 2,717 2,717 0 0 31,712 25,623 3,154 0 2,605 0 330 3,237 10%

2050 96 90 7 0 0 969 646 323 0 0 24,607 18,746 3,328 766 0 15 1,752 0 25,672 19,481 3,658 766 0 15 1,752 0 19%

table 13.2.4: Oecd north america: installed capacity gw 2012 2020 total generation 1,356 1,472 fossil 932 959 hard coal (& non-renewable waste) 163 161 lignite 188 171 gas (w/o h2) 495 570 oil 75 45 diesel 11 12 nuclear 124 123 hydrogen (fuel cells, gas power plants, gas chp) 0 0 renewables 300 391 hydro 204 208 wind 67 109 of which wind offshore 0 2 pv 9 40 biomass (& renewable waste) 16 24 geothermal 4 6 solar thermal power plants 1 5 ocean energy 0 0 fluctuating res (pv, wind, ocean) 75 148 share of fluctuating res 6% 10% res share (domestic generation) 27% 22%

2025 1,544 986 157 183 598 38 11 123 0 435 213 127 3 55 28 6 7 0 182 12% 28%

table 13.2.5: Oecd north america: final energy demand pj/a 2012 2020 total (incl. non-energy use) 73,586 79,453 total energy use1 67,806 72,296 transport 29,748 30,504 oil products 27,723 27,992 natural gas 842 956 biofuels 1,139 1,499 synfuels 0 0 electricity 44 58 RES electricity 8 12 hydrogen 0 0 res share transport 4% 5% industry 15,780 14,131 electricity 4,191 4,804 RES electricity 772 1,040 public district heat 241 256 RES district heat 8 14 hard coal & lignite 988 1,102 oil products 1,406 1,417 gas 5,943 6,555 solar 0 8 biomass 1,358 1,634 geothermal 4 4 hydrogen 0 0 res share industry 15% 17% other sectors 23,927 26,012 electricity 11,819 13,142 RES electricity 2,177 2,846 public district heat 57 49 RES district heat 2 3 hard coal & lignite 49 37 oil products 3,119 2,816 gas 7,906 8,813 solar 68 117 biomass 905 1,032 geothermal 5 6 hydrogen 0 0 res share other sectors 13% 15% total res 6,446 8,217 res share 10% 11% non energy use 5,780 7,157 oil 4,932 5,778 gas 842 1,377 coal 6 1

2025 80,815 73,628 30,579 27,643 1,064 1,793 0 80 18 0 6% 15,973 4,961 1,124 240 13 1,050 1,372 6,574 12 1,759 4 0 18% 27,075 13,982 3,168 40 2 33 2,641 9,072 186 1,114 6 0 17% 9,199 12% 7,188 5,488 1,700 0

2030 1,616 1,013 164 185 625 30 10 123 0 479 217 144 5 70 31 7 9 1 215 13% 30%

2040 1,742 1,075 177 189 680 17 12 120 0 547 214 175 11 99 37 8 11 2 276 16% 31%

2030 82,178 74,959 30,654 27,294 1,173 2,086 0 101 24 0 7% 16,166 5,119 1,206 224 13 998 1,328 6,593 16 1,884 4 0 19% 28,139 14,822 3,491 32 2 29 2,467 9,331 256 1,195 6 0 18% 10,182 14% 7,219 5,239 1,979 0

2040 85,148 78,064 31,170 26,341 1,781 2,857 0 191 47 0 9% 16,503 5,408 1,324 199 12 907 1,263 6,572 22 2,128 4 0 21% 30,392 16,734 4,095 11 1 20 2,024 9,782 452 1,362 7 0 19% 12,310 16% 7,084 4,675 2,409 0

2050 1,943 1,197 182 201 797 8 9 120 0 626 214 207 20 133 45 10 14 4 343 18% 32%

2050 88,579 81,630 31,712 25,623 2,605 3,154 0 330 83 0 10% 16,894 5,726 1,443 174 10 732 1,188 6,626 29 2,415 4 0 23% 33,024 18,677 4,707 3 0 14 1,746 10,293 737 1,548 7 0 21% 14,138 17% 6,949 3,945 3,005 0

1 excluding heat produced by chp autoproducers

table 13.2.6: Oecd north america: cO2 emissions mill t/a 2012 condensation power plants 2,203 hard coal (& non-renewable waste) 662 lignite 988 gas 495 oil 51 diesel 6 combined heat and power plants 162 hard coal (& non-renewable waste) 38 lignite 4 gas 111 oil 9 co2 emissions power and chp plants 2,365 hard coal (& non-renewable waste) 700 lignite 992 gas 606 oil & diesel 66 co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation 708 co2 intensity total electr. generation 455 co2 emissions by sector 5,949 % of 1990 emissions (5,554 mill t) 107% industry1 558 other sectors1 659 transport 1,998 power generation2 2,313 other conversion3 421 population (mill.) 477 co2 emissions per capita (t/capita) 12.5

2020 2,349 778 1,010 523 30 8 151 35 2 108 6 2,500 813 1,012 631 44

2025 2,422 772 1,061 557 24 7 135 28 2 100 5 2,557 801 1,064 657 36

2030 2,490 815 1,055 596 18 7 121 23 2 92 4 2,611 838 1,057 688 28

2040 2,670 893 1,049 710 11 6 102 18 2 81 1 2,771 911 1,051 791 18

2050 2,750 799 1,060 881 6 4 86 8 2 75 1 2,837 807 1,062 956 11

697 431 6,135 111% 603 685 2,021 2,447 379 512 12.0

678 418 6,156 111% 597 686 2,001 2,503 369 532 11.6

660 406 6,173 111% 592 687 1,980 2,555 359 551 11.2

622 388 6,258 113% 580 680 1,942 2,713 344 582 10.8

573 360 6,306 114% 563 686 1,933 2,777 347 606 10.4

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.2.7: Oecd north america: primary energy demand pj/a 2012 2020 total 107,517 115,339 fossil 89,639 93,589 hard coal (& non-renewable waste) 9,397 10,820 lignite 9,466 9,632 natural gas 30,696 31,332 crude oil 40,081 41,804 nuclear 9,872 10,371 renewables 8,006 11,380 hydro 2,488 2,628 wind 565 1,061 solar 111 376 biomass (& renewable waste) 4,270 6,284 geothermal 572 1,030 ocean energy 0 0 of which non-energy use 7,157 5,780 net electricity imports (final energy) -14 -10 total res incl. net electricity import 8,003 11,377 res share 7% 10%

2025 116,633 93,608 10,612 10,115 32,284 40,596 10,404 12,621 2,692 1,256 557 7,068 1,046 3 7,188 -10 12,618 11%

2030 118,064 93,732 10,993 10,051 33,249 39,439 10,438 13,895 2,756 1,450 738 7,836 1,109 6 7,219 -10 13,892 12%

2040 122,278 95,323 11,707 9,999 36,813 36,804 10,217 16,738 2,871 1,804 1,129 9,739 1,176 19 7,084 -10 16,736 14%

2050 125,987 97,087 10,362 10,104 42,134 34,488 10,196 18,704 2,902 2,178 1,659 10,666 1,253 44 6,949 -10 18,701 15%

o e c d n o r t h a m e r i ca : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.2.8 Oecd north america: electricity generation twh/a 2012 2020 4,856 4,975 768 477 941 709 1,234 1,607 0 0 75 40 9 7 905 508 42 44 691 741 157 559 0 16 9 203 24 49 1 16 0 17 347 398 42 38 5 0 254 279 0 0 12 6 34 64 0 4 0 6

194 153 5,203 3,340 810 946 1,487 87 9 905 0 0 958 691 157 9 76 24 1 0 358 382 0 0 4,459 166 3% 18%

221 177 5,373 3,162 515 709 1,885 46 7 508 6 2 1,697 741 559 203 109 53 16 17 399 362 31 0 4,578 778 14% 32%

2025 5,259 278 374 1,558 0 31 5 374 34 765 1,095 50 542 87 87 29 435 30 0 283 0 3 88 16 15

2030 5,725 210 27 1,459 0 16 3 53 26 776 1,527 109 964 173 415 77 496 19 0 296 0 2 119 35 25

2040 6,704 85 0 887 0 4 1 0 14 782 2,153 451 1,252 301 957 269 548 4 0 242 0 1 166 86 48

2050 6,649 0 0 147 0 1 0 0 16 782 2,306 578 1,318 409 1,209 460 502 0 0 121 4 1 182 141 57

231 205 5,694 2,562 308 374 1,841 35 5 374 15 7 2,743 765 1,095 542 121 103 87 29 414 374 162 0 4,741 1,666 29% 48%

250 246 6,221 2,032 229 27 1,756 18 3 53 25 17 4,111 776 1,527 964 144 208 415 77 431 388 477 0 4,922 2,568 41% 66%

262 286 7,252 1,224 88 0 1,129 5 1 0 48 40 5,980 782 2,153 1,252 180 387 957 269 453 411 1,178 0 5,207 3,674 51% 83%

238 264 7,151 267 0 0 264 3 0 0 61 58 6,823 782 2,306 1,318 198 550 1,209 460 446 405 1,690 0 4,607 4,085 57% 96%

table 13.2.9 Oecd north america: final energy consumption in transport pj/a 2012 2020 2025 2030 road 25,564 22,925 20,439 17,497 fossil fuels 24,388 21,554 18,129 13,380 biofuels 1,139 1,185 1,131 1,089 synfuels 0 0 0 0 natural gas 32 10 59 128 hydrogen 0 11 178 794 electricity 5 166 943 2,106 rail 663 676 697 686 fossil fuels 624 567 489 389 biofuels 0 34 63 81 synfuels 0 0 0 0 electricity 39 75 145 217 navigation 550 566 576 598 fossil fuels 550 550 548 528 biofuels 0 16 28 70 synfuels 0 0 0 0 aviation 2,161 2,047 1,922 1,762 fossil fuels 2,161 2,047 1,868 1,596 biofuels 0 0 54 166 synfuels 0 0 0 0 total (incl. pipelines) 29,748 26,878 24,224 21,060 fossil fuels 27,723 24,717 21,034 15,894 biofuels (incl. biogas) 1,139 1,235 1,276 1,405 synfuels 0 0 0 0 natural gas 842 670 640 624 hydrogen 0 11 178 794 electricity 44 243 1,097 2,343 total res 1,147 1,316 1,891 3,486 res share 4% 5% 8% 17% table 13.2.10 Oecd north america: heat supply pj/a 2012 0 0 0 0 0 867 779 88 0 0 19,082 15,798 1,697 68 0 14 1,506 0 19,949 16,577 1,784 68 0 14 1,506 0 11%

2020 103 0 55 25 23 1,119 799 247 32 42 20,003 15,559 1,896 549 73 245 1,680 0 21,226 16,358 2,198 574 128 245 1,680 42 18%

2025 352 0 146 114 92 1,456 842 370 135 108 19,331 13,652 1,800 1,345 111 625 1,751 47 21,139 14,494 2,316 1,459 338 625 1,751 156 27%

2030 653 0 224 239 189 1,903 888 550 286 179 18,515 11,415 1,593 2,309 149 1,135 1,778 137 21,072 12,303 2,367 2,548 625 1,135 1,778 316 39%

2040 11,049 4,003 583 0 183 2,113 4,168 710 259 103 0 348 637 437 200 0 1,582 1,190 392 0 14,347 5,889 1,278 0 487 2,113 4,582 6,835 48%

2040 1,553 0 378 642 534 2,678 762 884 688 344 15,967 5,645 1,143 3,979 219 2,630 1,925 426 20,198 6,407 2,405 4,620 1,440 2,630 1,925 770 67%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2050 7,927 700 453 0 200 3,212 3,362 559 84 56 0 418 696 357 339 0 1,678 1,007 671 0 11,083 2,148 1,520 0 271 3,212 3,932 8,396 76%

2050 1,823 0 152 904 768 3,120 406 1,188 1,105 421 13,373 1,597 592 4,372 208 3,736 2,201 667 18,316 2,003 1,932 5,275 2,080 3,736 2,201 1,089 89%

table 13.2.10: Oecd north america: installed capacity gw 2012 2020 total generation 1,356 1,472 fossil 932 801 hard coal (& non-renewable waste) 163 87 lignite 188 122 gas (w/o h2) 495 545 oil 75 39 diesel 11 7 nuclear 124 66 hydrogen (fuel cells, gas power plants, gas chp) 0 2 renewables 300 604 hydro 204 213 wind 67 206 of which wind offshore 0 5 pv 9 145 biomass (& renewable waste) 16 21 geothermal 4 8 solar thermal power plants 1 5 ocean energy 0 5 fluctuating res (pv, wind, ocean) 75 356 share of fluctuating res 6% 24% res share (domestic generation) 22% 41% table 13.2.12: Oecd north america: final energy demand pj/a 2012 2020 total (incl. non-energy use) 73,586 72,407 total energy use1 67,806 65,608 transport 29,748 26,878 oil products 27,723 24,717 natural gas 842 670 biofuels 1,139 1,235 synfuels 0 0 electricity 44 243 RES electricity 8 77 hydrogen 0 11 res share transport 4% 5% industry 14,131 14,805 electricity 4,191 4,746 RES electricity 772 1,501 public district heat 241 284 RES district heat 15 105 hard coal & lignite 988 833 oil products 1,406 1,103 gas 5,943 5,956 solar 0 150 biomass 1,358 1,583 geothermal 4 151 hydrogen 0 0 res share industry 15% 24% other sectors 23,927 23,925 electricity 11,819 11,493 RES electricity 2,177 3,634 public district heat 57 144 RES district heat 4 53 hard coal & lignite 49 22 oil products 3,119 2,454 gas 7,906 8,270 solar 68 399 biomass 905 1,050 geothermal 5 94 hydrogen 0 0 res share other sectors 13% 22% total res 6,455 10,035 res share 10% 15% non energy use 5,780 6,799 oil 4,932 5,378 gas 842 697 coal 6 724

2025 1,879 761 51 64 606 34 5 48 4 1,066 219 397 14 379 23 15 25 9 784 42% 57%

2025 68,013 61,544 24,224 21,034 640 1,276 0 1,097 530 178 8% 14,269 4,910 2,371 294 163 633 796 5,419 383 1,550 229 54 33% 23,051 11,060 5,342 504 280 0 1,924 7,329 961 950 323 0 34% 14,472 24% 6,469 4,285 650 1,534

2030 2,328 693 46 5 621 18 3 7 7 1,621 225 544 30 668 27 31 101 26 1,238 53% 70%

2040 2,814 626 18 0 599 7 2 0 13 2,175 230 730 124 850 33 56 181 96 1,675 60% 77%

2030 62,729 56,593 21,060 15,894 624 1,405 0 2,343 1,554 794 17% 13,560 4,882 3,239 304 206 392 514 5,025 588 1,368 333 154 43% 21,973 10,494 6,963 929 631 0 1,305 6,051 1,720 845 629 0 49% 20,110 36% 6,136 3,544 525 2,067

2040 50,750 45,438 14,347 5,889 487 1,278 0 4,582 3,803 2,113 48% 11,765 4,931 4,093 307 262 111 205 3,281 916 934 620 461 61% 19,325 9,234 7,666 2,076 1,773 0 549 2,352 3,063 524 1,528 0 75% 28,597 63% 5,313 1,845 340 3,128

2050 2,785 416 0 0 412 4 0 0 17 2,353 233 763 156 869 62 80 198 149 1,780 64% 84%

2050 41,781 37,264 11,083 2,148 271 1,520 0 3,932 3,784 3,212 76% 9,918 5,033 4,843 276 262 0 8 1,684 966 532 716 702 81% 16,263 7,619 7,332 2,515 2,390 0 55 203 3,405 173 2,294 0 96% 31,985 86% 4,517 539 191 3,787

1 excluding heat produced by chp autoproducers

table 13.2.13: Oecd north america: cO2 emissions mill t/a 2012 condensation power plants 2,203 hard coal (& non-renewable waste) 662 lignite 988 gas 495 oil 51 diesel 6 combined heat and power plants 162 hard coal (& non-renewable waste) 38 lignite 4 gas 111 oil 9 co2 emissions power and chp plants 2,365 hard coal (& non-renewable waste) 700 lignite 992 gas 606 oil & diesel 66 co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation 708 co2 intensity total electr. generation 455 co2 emissions by sector 5,949 % of 1990 emissions (5,554 mill t) 107% industry1 558 other sectors1 659 transport 1,998 power generation2 2,313 other conversion3 421 population (mill.) 477 co2 emissions per capita (t/capita) 12.5

2020 1,786 409 708 637 27 5 159 33 0 121 5 1,944 442 708 758 37

2025 1,222 236 362 598 21 4 151 26 0 122 2 1,372 263 362 720 27

2030 764 177 25 549 11 2 146 18 0 127 1 910 195 25 676 14

2040 395 69 0 322 2 1 109 4 0 105 1 504 73 0 427 4

2050 56 0 0 55 1 0 53 0 0 52 1 108 0 0 106 2

615 362 5,147 93% 520 632 1,780 1,889 325 512 10.1

536 241 4,087 74% 446 547 1,518 1,317 259 532 7.7

448 146 3,017 54% 375 444 1,151 853 194 551 5.5

412 70 1,385 25% 221 195 434 455 80 582 2.4

406 15 397 7% 103 35 165 76 17 606 0.7

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.2.14: Oecd north america: primary energy demand pj/a 2012 2020 total 107,517 101,342 fossil 89,639 82,289 hard coal (& non-renewable waste) 9,397 6,966 lignite 9,466 6,643 natural gas 30,696 31,708 crude oil 40,081 36,972 nuclear 9,872 5,542 renewables 8,006 13,511 hydro 2,488 2,668 wind 565 2,012 solar 111 1,363 biomass (& renewable waste) 4,270 5,675 geothermal 572 1,735 ocean energy 0 59 of which non-energy use 5,780 6,799 net electricity imports (final energy) -14 -10 total incl. net electricity import 8,003 13,508 res share 7% 13%

2025 92,037 68,485 5,402 3,399 29,046 30,638 4,075 19,478 2,755 3,943 3,724 5,806 3,145 104 6,469 -10 19,476 21%

2030 82,666 54,106 4,862 236 26,001 23,006 578 27,982 2,794 5,499 7,513 6,043 5,856 277 6,136 -10 27,786 34%

2040 69,040 28,340 4,206 0 15,084 9,051 0 40,699 2,815 7,753 12,573 5,802 10,788 968 5,313 -10 40,435 59%

2050 58,357 11,322 3,911 0 4,492 2,919 0 47,035 2,815 8,304 14,374 5,444 14,442 1,656 4,517 -10 46,706 80%

o e c d n o r t h a m e r i ca : a d va n c e d e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.2.15 Oecd north america: electricity generation twh/a 2012 2020 4,856 5,065 768 364 941 709 1,234 1,607 0 0 75 40 9 7 905 508 42 44 691 741 157 674 0 20 9 275 24 57 1 22 0 18 347 398 42 38 5 0 254 279 0 0 12 6 34 64 0 4 0 6

194 153 5,203 3,340 810 946 1,487 87 9 905 0 0 958 691 157 9 76 24 1 0 358 382 0 0 4,459 166 3% 18%

221 177 5,463 3,049 402 709 1,885 46 7 508 6 2 1,901 741 674 275 109 62 22 18 399 362 47 9 4,643 968 18% 35%

2025 5,755 159 374 1,558 16 31 5 374 34 765 1,417 60 779 106 118 34 435 30 0 283 3 3 88 16 15

2030 6,473 35 27 1,449 30 16 3 53 26 776 1,858 143 1,289 223 612 96 496 19 0 296 6 2 119 35 25

2040 7,833 24 0 851 103 4 1 0 14 782 2,524 582 1,531 457 1,312 343 548 4 0 242 29 1 166 86 48

2050 8,574 0 0 146 146 0 0 0 16 782 2,942 774 1,852 588 1,648 600 502 0 0 122 122 0 182 141 57

231 205 6,190 2,425 189 374 1,823 35 5 374 33 18 3,358 765 1,417 779 121 123 118 34 414 374 443 22 4,934 2,230 36% 55%

250 246 6,969 1,812 54 27 1,710 18 3 53 60 44 5,033 776 1,858 1,289 144 258 612 96 431 388 782 29 5,325 3,243 47% 73%

262 286 8,381 995 28 0 961 5 1 0 180 158 7,216 782 2,524 1,531 180 544 1,312 343 453 411 1,599 275 5,650 4,398 52% 88%

238 264 9,076 0 0 0 0 0 0 0 325 325 8,751 782 2,942 1,852 198 730 1,648 600 446 405 2,720 501 5,002 5,393 59% 100%

table 13.2.16 Oecd north america: final energy consumption in transport pj/a 2012 2020 2025 2030 road 25,564 22,542 19,288 15,624 fossil fuels 24,388 21,070 16,155 10,809 biofuels 1,139 1,150 1,159 989 synfuels 0 12 28 31 natural gas 32 0 0 0 hydrogen 0 52 660 1,247 electricity 5 270 1,314 2,579 rail 663 743 885 1,043 fossil fuels 624 536 427 299 biofuels 0 16 41 51 synfuels 0 0 1 2 electricity 39 190 416 691 navigation 550 566 576 598 fossil fuels 550 561 567 517 biofuels 0 6 8 78 synfuels 0 0 0 2 aviation 2,161 2,026 1,865 1,639 fossil fuels 2,161 2,016 1,846 1,426 biofuels 0 10 18 207 synfuels 0 0 0 6 total (incl. pipelines) 29,748 26,549 23,226 19,443 fossil fuels 27,723 24,183 18,995 13,051 biofuels (incl. biogas) 1,139 1,182 1,227 1,325 synfuels 0 13 30 41 natural gas 842 653 557 454 hydrogen 0 52 660 1,247 electricity 44 466 1,758 3,325 total res 1,147 1,367 2,562 4,691 res share 4% 5% 11% 24% table 13.2.17 Oecd north america: heat supply pj/a 2012 0 0 0 0 0 867 779 88 0 0 19,082 15,798 1,697 68 0 14 1,506 0 19,949 16,577 1,784 68 0 14 1,506 0 11%

2020 103 0 55 25 23 1,119 799 247 32 42 20,003 15,559 1,896 549 73 245 1,680 0 21,226 16,358 2,198 574 128 245 1,680 42 18%

2025 352 0 146 114 92 1,456 835 370 135 116 19,331 13,574 1,800 1,358 111 625 1,751 113 21,139 14,409 2,316 1,472 338 625 1,751 229 28%

2030 653 0 224 239 189 1,903 871 550 286 196 18,515 11,317 1,593 2,321 149 1,135 1,797 203 21,072 12,188 2,367 2,561 625 1,135 1,797 398 40%

2040 8,504 1,795 702 223 0 2,049 3,957 1,401 130 66 21 1,184 637 414 169 54 1,249 812 332 105 12,373 3,152 1,269 403 200 2,049 5,300 8,082 65%

2040 1,553 0 378 642 534 2,678 672 884 688 434 15,967 5,310 1,143 4,033 219 2,630 1,971 661 20,198 5,982 2,405 4,675 1,440 2,630 1,971 1,095 69%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

322

2050 5,477 0 278 138 0 2,501 2,699 1,399 0 47 23 1,329 696 0 465 231 1,091 0 729 361 9,009 0 1,520 753 0 2,501 4,236 9,009 100%

2050 1,824 0 152 904 768 3,118 0 1,188 1,105 825 13,375 0 592 4,388 203 3,737 2,351 2,103 18,316 0 1,932 5,292 2,076 3,737 2,351 2,928 100%

table 13.2.18: Oecd north america: installed capacity gw 2012 2020 total generation 1,356 1,554 fossil 932 785 hard coal (& non-renewable waste) 163 68 lignite 188 121 gas (w/o h2) 495 547 oil 75 41 diesel 11 7 nuclear 124 66 hydrogen (fuel cells, gas power plants, gas chp) 0 2 renewables 300 702 hydro 204 213 wind 67 248 of which wind offshore 0 6 pv 9 197 biomass (& renewable waste) 16 21 geothermal 4 9 solar thermal power plants 1 7 ocean energy 0 6 fluctuating res (pv, wind, ocean) 75 451 share of fluctuating res 6% 29% res share (domestic generation) 22% 45% table 13.2.19: Oecd north america: final energy demand pj/a 2012 2020 total (incl. non-energy use) 73,586 72,086 total energy use1 67,806 65,286 transport 29,748 26,549 oil products 27,723 24,183 natural gas 842 653 biofuels 1,139 1,182 synfuels 0 13 electricity 44 466 RES electricity 8 162 hydrogen 0 52 res share transport 4% 5% industry 14,131 14,805 electricity 4,191 4,746 RES electricity 772 1,653 public district heat 241 284 RES district heat 15 105 hard coal & lignite 988 833 oil products 1,406 1,103 gas 5,943 5,956 solar 0 150 biomass 1,358 1,583 geothermal 4 151 hydrogen 0 0 res share industry 15% 25% other sectors 23,927 23,932 electricity 11,819 11,502 RES electricity 2,177 4,006 public district heat 57 144 RES district heat 4 53 hard coal & lignite 49 22 oil products 3,119 2,452 gas 7,906 8,270 solar 68 399 biomass 905 1,050 geothermal 5 94 hydrogen 0 0 res share other sectors 13% 23% total res 6,455 10,611 res share 10% 16% non energy use 5,780 6,799 oil 4,932 5,378 gas 842 697 coal 6 724

2025 2,197 774 38 65 632 34 5 48 10 1,365 219 514 17 546 23 20 34 11 1,070 49% 62%

2025 67,040 60,571 23,226 18,995 557 1,227 30 1,758 959 660 11% 14,269 4,910 2,678 294 164 633 796 5,419 383 1,550 229 54 35% 23,075 11,094 6,051 504 281 5 1,916 7,236 974 950 323 73 37% 16,215 27% 6,469 4,285 650 1,534

2030 2,768 712 12 5 671 21 3 7 21 2,028 227 661 40 893 27 38 149 33 1,586 57% 73%

2040 3.290 575 12 0 552 8 2 0 89 2,626 239 852 159 1,038 33 95 248 122 2,011 61% 80%

2030 61,433 55,297 19,443 13,051 454 1,325 41 3,325 2,426 1,247 24% 13,623 4,994 3,644 304 208 387 479 5,065 588 1,368 333 105 46% 22,231 10,852 7,918 929 635 11 1,221 5,893 1,733 845 629 120 53% 22,756 41% 6,136 3,544 525 2,067

2040 49,361 44,048 12,373 3,152 200 1,269 403 5,300 4,658 2,049 65% 11,875 5,138 4,515 307 267 111 154 3,251 916 934 620 445 64% 19,800 9,903 8,703 2,076 1,805 13 389 1,986 3,117 524 1,528 265 80% 31,636 72% 5,313 1,845 340 3,128

2050 3.629 0 0 0 0 0 0 0 528 3,102 257 971 209 1,224 37 134 286 193 2,387 66% 85%

2050 40,402 35,885 9,009 0 0 1,520 753 4,236 4,236 2,501 100% 10,049 5,374 5,374 276 276 0 0 0 962 532 712 2,193 100% 16,826 8,396 8,396 2,516 2,516 0 0 0 3,426 173 2,294 21 100% 35,884 100% 4,517 539 191 3,787

1 excluding heat produced by chp autoproducers

table 13.2.20 Oecd north america: cO2 emissions mill t/a 2012 condensation power plants 2,203 hard coal (& non-renewable waste) 662 lignite 988 gas 495 oil 51 diesel 6 combined heat and power plants 162 hard coal (& non-renewable waste) 38 lignite 4 gas 111 oil 9 co2 emissions power and chp plants 2,365 hard coal (& non-renewable waste) 700 lignite 992 gas 606 oil & diesel 66 co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation 708 co2 intensity total electr. generation 455 co2 emissions by sector 5,949 % of 1990 emissions (5,554 mill t) 107% industry1 558 other sectors1 659 transport 1,998 power generation2 2,313 other conversion3 421 population (mill.) 477 co2 emissions per capita (t/capita) 12.5

2020 1,689 312 708 637 27 5 159 33 0 121 5 1,848 345 708 758 37

2025 1,115 135 362 592 21 4 150 26 0 121 2 1,264 162 362 713 27

2030 597 21 25 538 11 2 143 18 0 125 1 740 38 25 663 14

2040 299 27 0 269 2 1 97 4 0 92 1 396 31 0 361 4

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

606 338 4,990 90% 520 632 1,741 1,792 304 512 9.8

521 204 3,783 68% 446 542 1,368 1,210 218 532 7.1

409 106 2,570 46% 374 430 940 684 143 551 4.7

398 47 990 18% 213 162 227 352 35 582 1.7

0 0 0 0% 0 0 0 0 0 606 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.2.21: Oecd north america: primary energy demand pj/a 2012 2020 total 107,517 100,471 fossil 89,639 80,551 hard coal (& non-renewable waste) 9,397 5,793 lignite 9,466 6,643 natural gas 30,696 31,732 crude oil 40,081 36,382 nuclear 9,872 5,542 renewables 8,006 14,379 hydro 2,488 2,668 wind 565 2,427 solar 111 1,643 biomass (& renewable waste) 4,270 5,595 geothermal 572 1,979 ocean energy 0 66 of which non-energy use 5,780 6,799 net electricity imports (final energy) -14 -10 total incl. net electricity import 8,003 14,375 res share 7% 14%

2025 90,855 64,743 4,175 3,399 28,766 28,402 4,075 22,038 2,755 5,103 4,703 5,735 3,619 122 6,469 -10 22,036 24%

2030 81,241 48,501 2,985 236 25,492 19,787 578 32,161 2,794 6,690 9,406 5,931 6,997 344 6,136 -10 31,946 39%

2040 70,388 22,634 3,624 0 13,129 5,881 0 47,754 2,815 9,088 14,914 5,791 13,913 1,234 5,313 -10 47,474 67%

2050 61,106 4,528 3,788 0 201 539 0 56,579 2,815 10,592 17,893 5,444 17,675 2,159 4,517 -10 56,236 92%

o e c d n o r t h a m e r i ca : i n v e st m e n t a n d e m p loy m e n t table 13.2.22: Oecd north america: investments in electricity generation unit 20122021203120412012unit ref 2020 2030 2040 2050 2050 fossil (w/o chp) billion $ 354.1 462.1 606.2 458.1 1,880.4 billion $/a nuclear billion $ 123.3 155.4 129.1 160.3 568.2 billion $/a chp (fossil + renewable) billion $ 88.1 47.8 11.9 5.9 153.7 billion $/a renewables (w/o chp) billion $ 380.6 398.3 433.5 462.0 1,674.5 billion $/a total billion $ 946.2 1,063.6 1,180.7 1,086.3 4,276.8 billion $/a conventional (fossil & nuclear) billion $ 555.6 658.0 746.2 621.9 2,581.6 billion $/a renewables billion $ 390.5 405.6 434.5 464.5 1,695.2 billion $/a biomass billion $ 40.1 34.5 45.2 43.4 163.3 billion $/a hydro billion $ 120.1 139.0 97.1 105.2 461.4 billion $/a wind billion $ 109.5 139.7 182.8 192.0 623.9 billion $/a pv billion $ 64.4 44.6 66.5 53.2 228.8 billion $/a geothermal billion $ 32.7 24.7 18.4 25.4 101.1 billion $/a solar thermal power plants billion $ 23.7 21.0 20.5 40.7 105.9 billion $/a ocean energy billion $ 0.0 2.2 4.0 4.5 10.7 billion $/a e[r] fossil (w/o chp) billion $ 183.9 213.6 319.0 96.9 813.5 billion $/a nuclear billion $ 4.5 0.0 0.0 0.0 4.5 billion $/a chp (fossil + renewable) billion $ 134.2 143.6 134.0 230.8 642.6 billion $/a renewables (w/o chp) billion $ 802.4 2,306.2 1,979.3 1,759.9 6,847.7 billion $/a total billion $ 1,124.9 2,663.4 2,432.3 2,087.6 8,308.2 billion $/a conventional (fossil & nuclear) billion $ 280.9 266.4 333.6 105.2 986.1 billion $/a renewables billion $ 844.0 2,397.0 2,098.7 1,982.4 7,322.1 billion $/a biomass billion $ 41.9 49.3 59.4 139.8 290.4 billion $/a hydro billion $ 137.3 144.9 123.5 117.6 523.4 billion $/a wind billion $ 293.1 718.6 756.8 755.5 2,524.0 billion $/a pv billion $ 249.9 696.1 327.5 424.6 1,698.1 billion $/a geothermal billion $ 60.4 190.3 183.5 211.0 645.1 billion $/a solar thermal power plants billion $ 28.0 497.7 411.0 202.3 1,139.0 billion $/a ocean energy billion $ 33.3 100.1 237.0 131.7 502.1 billion $/a adv e[r] fossil (w/o chp) billion $ 135.6 214.8 405.6 147.0 903.0 billion $/a nuclear billion $ 4.5 0.0 0.0 0.0 4.5 billion $/a chp (fossil + renewable) billion $ 134.2 146.2 136.4 142.7 559.4 billion $/a renewables (w/o chp) billion $ 998.3 3,015.7 2,479.2 2,665.7 9,158.9 billion $/a total billion $ 1,272.7 3,376.7 3,021.1 2,955.4 10,625.8 billion $/a conventional (fossil & nuclear) billion $ 232.7 270.1 422.5 156.1 1,081.5 billion $/a renewables billion $ 1,039.9 3,106.6 2,598.6 2,799.2 9,544.3 billion $/a biomass billion $ 41.9 49.3 59.4 50.8 201.4 billion $/a hydro billion $ 137.3 153.8 146.4 164.0 601.5 billion $/a wind billion $ 372.6 867.4 879.2 1,054.1 3,173.4 billion $/a pv billion $ 339.4 932.2 343.1 694.0 2,308.7 billion $/a geothermal billion $ 74.6 237.7 359.8 311.7 983.7 billion $/a solar thermal power plants billion $ 37.2 738.3 506.6 351.6 1,633.7 billion $/a ocean energy billion $ 36.9 127.7 304.1 173.0 641.8 billion $/a

annual average

2012-2050 48.2 14.6 3.9 42.9 109.7 66.2 43.5 4.2 11.8 16.0 5.9 2.6 2.7 0.3 20.9 0.1 16.5 175.6 213.0 25.3 187.7 7.4 13.4 64.7 43.5 16.5 29.2 12.9 23.2 0.1 14.3 234.8 272.5 27.7 244.7 5.2 15.4 81.4 59.2 25.2 41.9 16.5

table 13.2.23: Oecd north america: investments unit 2012ref 2020 heat pumps billion $ 1.2 deep geothermal billion $ 0.0 solar thermal billion $ 27.7 biomass billion $ 135.9 total billion $ 164.8 e[r] heat pumps billion $ 62.0 deep geothermal billion $ 31.8 solar thermal billion $ 156.0 bomass billion $ 139.4 total billion $ 389.2 adv e[r] heat pumps billion $ 62.0 deep geothermal billion $ 31.8 solar thermal billion $ 156.0 biomass billion $ 139.4 total billion $ 389.2

in renewable heat generation 2021203120412012unit 2030 2040 2050 2050 1.3 0.4 0.4 3.3 billion $/a 0.0 0.0 0.0 0.0 billion $/a 48.7 67.2 97.4 241.1 billion $/a 136.6 69.9 72.0 414.5 billion $/a 186.6 137.6 169.8 658.9 billion $/a

2012-2050 0.1 0.0 6.2 10.6 16.9

263.3 25.1 503.3 10.3 802.0

460.9 231.0 578.0 12.1 1,281.9

527.1 198.0 348.7 0.0 1,073.8

1,313.2 billion $/a 485.8 billion $/a 1,586.0 billion $/a 161.8 billion $/a 3,546.9 billion $/a

33.7 12.5 40.7 4.1 90.9

263.3 25.1 507.0 10.3 805.7

460.9 231.0 589.0 12.1 1,292.9

527.3 198.2 347.0 0.0 1,072.5

1,313.4 billion $/a 486.1 billion $/a 1,599.1 billion $/a 161.8 billion $/a 3,560.3 billion $/a

33.7 12.5 41.0 4.1 91.3

table 13.2.24: Oecd north america: total employment in the energy sector

thousand jobs adv e [ r ] scenariO

reference scenariO

by sector construction and installation manufacturing operations and maintenance fuel supply (domestic) coal and gas export solar and geothermal heat total jobs (thousands) by technology coal gas, oil & diesel nuclear renewable biomass hydro wind pv geothermal power solar thermal power ocean solar - heat geothermal & heat pump total jobs (thousands)

annual average

2015 138 119 380 551 89 1,278

2020 83 75 402 526 59 1,145

2025 90 72 405 514 71 1,152

2030 85 58 407 502 68 1,120

2020 388 437 443 540 243 2,051

2025 458 516 535 513 753 2,774

2030 442 533 623 475 691 2,764

294 175 84 725 276 60 129 164 1.8 5.5 0.6 74 14.7 1,278

253 178 82 631 296 57 116 93 1.6 6.5 2.3 48 10.7 1,145

228 180 81 662 313 59 122 86 1.5 7.2 2.7 60 10.2 1,152

209 176 80 654 328 58 110 70 1.4 10.0 8.7 59 9.6 1,120

246 162 96 1,547 391 48 341 468 10 29 16.6 186 57 2,051

177 166 101 2,330 459 48 434 517 15 71 32 636 117 2,774

135 157 110 2,363 455 51 486 512 20 102 46 544 146 2,764

323

l at i n a m e r i ca : r e f e r e n c e s c e n a r i o table 13.3.1 latin america: electricity generation twh/a 2012 power plants 1,152 hard coal (& non-renewable waste) 31 lignite 7 gas 198 of which from H2 0 oil 121 diesel 29 nuclear 22 biomass (& renewable waste) 10 hydro 722 wind 8 of which wind offshore 0 pv 0 geothermal 4 solar thermal power plants 0 ocean energy 0 combined heat and power plants 63 hard coal (& non-renewable waste) 1 lignite 0 gas 16 of which from H2 0 oil 6 biomass (& renewable waste) 40 geothermal 0 hydrogen 0 CHP by producer main activity producers 0 autoproducers 63 total generation 1,216 fossil 409 hard coal (& non-renewable waste) 32 lignite 8 gas 213 oil 127 diesel 29 nuclear 22 hydrogen 0 of which renewable H2 0 renewables (w/o renewable hydrogen) 784 hydro 722 wind 8 pv 0 biomass (& renewable waste) 50 geothermal 4 solar thermal power plants 0 ocean energy 0 distribution losses 179 own consumption electricity 50 electricity for hydrogen production 0 electricity for synfuel production 0 final energy consumption (electricity) 987 fluctuating res (pv, wind, ocean) 8 share of fluctuating res 1% res share (domestic generation) 64%

2020 1,495 70 8 247 0 95 33 34 27 921 48 1 6 6 0 0 72 0 0 17 0 7 48 0 0

2025 1,742 80 8 340 0 75 37 41 37 1,029 73 2 10 10 2 0 75 0 0 16 0 7 52 0 0

2030 1,989 90 9 434 0 55 41 48 46 1,137 98 4 15 13 3 0 79 0 0 16 0 7 55 0 0

2040 2,490 125 10 639 0 33 54 58 66 1,319 130 10 24 21 11 1 85 0 0 15 0 7 63 0 0

2050 2,904 234 11 778 0 15 63 71 75 1,400 170 20 36 25 23 2 92 0 0 15 0 8 69 0 0

0 72 1,567 476 70 8 264 101 33 34 0 0 1,057 921 48 6 75 6 0 0 233 55 0 0 1,285 54 3% 67%

0 75 1,817 564 81 9 356 82 37 41 0 0 1,212 1,029 73 10 89 10 2 0 272 53 0 0 1,498 83 5% 67%

0 78 2,067 652 90 9 449 62 41 48 0 0 1,368 1,137 98 15 102 13 3 0 310 52 0 0 1,711 113 5% 66%

0 85 2,576 884 125 10 654 40 54 58 0 0 1,633 1,319 130 24 129 21 11 1 390 42 0 0 2,150 155 6% 63%

0 92 2,996 1,124 234 11 793 23 63 71 0 0 1,801 1,400 170 36 144 25 23 2 454 42 0 0 2,505 208 7% 60%

table 13.3.2 latin america: final energy consumption in transport pj/a 2012 2020 2025 road 6,326 7,489 8,286 fossil fuels 5,561 6,292 6,792 biofuels 557 944 1,215 synfuels 0 0 0 natural gas 207 252 273 hydrogen 0 0 0 electricity 0 2 5 rail 128 156 196 fossil fuels 109 137 176 biofuels 0 0 0 synfuels 0 0 0 electricity 18 19 20 navigation 122 150 168 fossil fuels 122 150 168 biofuels 0 0 0 synfuels 0 0 0 aviation 200 252 288 fossil fuels 200 252 288 biofuels 0 0 0 synfuels 0 0 0 total (incl. pipelines) 6,839 8,135 9,037 fossil fuels 5,993 6,831 7,424 biofuels (incl. biogas) 557 944 1,215 synfuels 0 0 0 natural gas 271 339 373 hydrogen 0 0 0 electricity 18 22 25 total res 569 958 1,232 res share 8% 12% 14%

2030 9,093 7,303 1,486 0 295 0 8 225 204 0 0 21 186 186 0 0 324 324 0 0 9,939 8,018 1,486 0 407 0 29 1,505 15%

2040 10,099 7,863 1,836 0 384 0 16 284 261 0 0 23 223 223 0 0 386 386 0 0 11,126 8,732 1,836 0 519 0 39 1,861 17%

2050 9,856 7,480 1,856 0 494 0 26 343 317 0 0 25 259 259 0 0 418 418 0 0 11,035 8,474 1,856 0 653 0 51 1,887 17%

table 13.3.3 latin america: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 134 60 74 0 0 7,354 4,221 2,241 22 0 0 870 0 7,487 4,281 2,314 22 0 0 870 0 39%

2020 0 0 0 0 0 176 67 108 0 0 9,056 5,568 2,404 54 0 0 1,030 0 9,232 5,635 2,512 54 0 0 1,030 0 35%

2025 0 0 0 0 0 199 68 131 0 0 10,240 6,430 2,595 74 0 0 1,140 0 10,439 6,499 2,726 74 0 0 1,140 0 34%

2030 0 0 0 0 0 230 69 161 0 0 11,433 7,311 2,789 94 0 0 1,240 0 11,664 7,380 2,950 94 0 0 1,240 0 33%

2040 0 0 0 0 0 332 73 259 0 0 14,049 9,092 3,358 149 0 0 1,450 0 14,381 9,165 3,616 149 0 0 1,450 0 33%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

324

2050 0 0 0 0 0 580 81 500 0 0 15,669 10,167 3,713 220 0 0 1,570 0 16,250 10,247 4,213 220 0 0 1,570 0 33%

table 13.3.4: latin america: installed capacity gw 2012 total generation 272 fossil 103 hard coal (& non-renewable waste) 6 lignite 2 gas (w/o h2) 54 oil 34 diesel 8 nuclear 3 hydrogen (fuel cells, gas power plants, gas chp) 0 renewables 166 hydro 148 wind 4 of which wind offshore 0 pv 0 biomass (& renewable waste) 14 geothermal 1 solar thermal power plants 0 ocean energy 0 fluctuating res (pv, wind, ocean) 4 share of fluctuating res 1% res share (domestic generation) 61%

2020 370 135 13 2 74 35 11 5 0 231 192 16 0 4 18 1 0 0 20 5% 62%

table 13.3.5: latin america: final energy demand pj/a 2012 2020 total (incl. non-energy use) 20,497 24,678 total energy use1 18,999 23,122 transport 6,839 8,135 oil products 5,993 6,831 natural gas 271 339 biofuels 557 944 synfuels 0 0 electricity 18 22 RES electricity 12 15 hydrogen 0 0 res share transport 8% 12% industry 6,962 8,680 electricity 1,569 1,997 RES electricity 1,012 1,347 public district heat 1 2 RES district heat 1 2 hard coal & lignite 373 708 oil products 1,627 1,771 gas 1,518 2,061 solar 0 9 biomass 1,874 2,131 geothermal 0 0 hydrogen 0 0 res share industry 41% 40% other sectors 5,198 6,306 electricity 1,967 2,607 RES electricity 1,269 1,758 public district heat 0 0 RES district heat 0 0 hard coal & lignite 3 6 oil products 1,269 1,629 gas 566 675 solar 22 44 biomass 1,370 1,345 geothermal 0 0 hydrogen 0 0 res share other sectors 51% 50% total res 6,116 7,595 res share 32% 33% non energy use 1,498 1,557 oil 969 845 gas 524 706 coal 5 6

2025 430 155 14 2 96 30 13 5 0 270 217 23 1 8 20 1 0 0 31 7% 63%

2025 27,531 25,974 9,037 7,424 373 1,215 0 25 17 0 14% 9,690 2,267 1,512 2 2 813 1,823 2,453 14 2,319 0 0 40% 7,247 3,100 2,068 0 0 7 1,927 759 60 1,393 0 0 49% 8,599 33% 1,557 802 748 6

2030 490 175 15 2 118 24 16 6 0 309 242 31 1 11 22 2 1 0 42 8% 63%

2030 30,383 28,826 9,939 8,018 407 1,486 0 29 19 0 15% 10,699 2,536 1,678 2 2 917 1,876 2,844 18 2,506 0 0 39% 8,187 3,593 2,377 0 0 8 2,226 843 76 1,441 0 0 48% 9,603 33% 1,557 757 793 6

2040 604 223 20 2 163 16 22 8 0 374 285 40 2 17 26 3 3 0 57 9% 62%

2050 695 268 37 2 194 9 26 9 0 418 304 51 5 26 29 4 5 0 77 11% 60%

2040 35,460 33,903 11,126 8,732 519 1,836 0 39 25 0 17% 12,817 3,134 1,988 2 2 1,110 1,937 3,744 33 2,857 0 0 38% 9,960 4,565 2,896 0 0 10 2,715 1,013 116 1,539 0 0 46% 11,291 33% 1,557 668 883 6

2050 37,865 36,308 11,035 8,474 653 1,856 0 51 31 0 17% 14,215 3,729 2,241 3 2 1,147 1,830 4,453 49 3,004 0 0 37% 11,059 5,240 3,150 0 0 12 2,949 1,135 171 1,552 0 0 44% 12,057 33% 1,557 638 919 0

1 excluding heat produced by chp autoproducers

table 13.3.6: latin america: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (578 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 248 34 10 101 67 37 15 1 0 10 4 263 35 10 111 107

2020 289 65 9 113 61 40 14 0 0 10 4 303 65 9 123 106

2025 313 73 9 144 48 39 14 0 0 9 4 327 74 9 153 91

2030 338 80 9 175 35 38 13 0 0 8 4 351 80 9 183 78

2040 430 107 10 250 21 43 12 0 0 8 4 443 107 10 258 67

2050 572 200 11 302 10 50 12 0 0 7 4 584 200 11 309 64

643 216 1,226 212% 262 130 470 248 116 485 2.5

636 193 1,419 245% 334 165 537 289 94 526 2.7

579 180 1,561 270% 370 193 584 313 102 549 2.8

538 170 1,703 295% 405 220 630 338 109 569 3.0

501 172 1,989 344% 479 268 690 430 122 601 3.3

520 195 2,176 377% 514 293 677 572 120 622 3.5

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.3.7: latin america: primary energy demand pj/a 2012 2020 total 27,122 32,446 fossil 18,956 22,162 hard coal (& non-renewable waste) 1,060 1,621 lignite 117 106 natural gas 5,802 7,173 crude oil 11,977 13,262 nuclear 245 370 renewables 7,921 9,915 hydro 2,601 3,317 wind 27 174 solar 22 75 biomass (& renewable waste) 5,139 6,169 geothermal 132 180 ocean energy 0 0 of which non-energy use 1,557 1,498 net electricity imports (final energy) 4 20 total res incl. net electricity import 7,924 9,928 res share 29% 31%

2025 36,005 24,373 1,912 107 8,327 14,027 445 11,187 3,705 263 117 6,867 235 1 1,557 20 11,200 31%

2030 39,555 26,568 2,202 110 9,452 14,804 519 12,468 4,093 352 159 7,573 291 1 1,557 20 12,481 32%

2040 46,213 30,952 2,831 117 12,159 15,845 636 14,625 4,747 469 273 8,717 415 3 1,557 20 14,638 32%

2050 48,786 32,506 3,960 124 12,800 15,622 771 15,510 5,042 612 435 8,965 450 6 1,557 20 15,522 32%

energy

l at i n a m e r i ca : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.3.8 latin america: electricity generation twh/a 2012 power plants 1,152 hard coal (& non-renewable waste) 31 lignite 7 gas 198 of which from H2 0 oil 121 diesel 29 nuclear 22 biomass (& renewable waste) 10 hydro 722 wind 8 of which wind offshore 0 pv 0 geothermal 4 solar thermal power plants 0 ocean energy 0 combined heat and power plants 63 hard coal (& non-renewable waste) 1 lignite 0 gas 16 of which from H2 0 oil 6 biomass (& renewable waste) 40 geothermal 0 hydrogen 0 CHP by producer main activity producers 0 autoproducers 63 total generation 1,216 fossil 409 hard coal (& non-renewable waste) 32 lignite 8 gas 213 oil 127 diesel 29 nuclear 22 hydrogen 0 of which renewable H2 0 renewables (w/o renewable hydrogen) 784 hydro 722 wind 8 pv 0 biomass (& renewable waste) 50 geothermal 4 solar thermal power plants 0 ocean energy 0 distribution losses 179 own consumption electricity 50 electricity for hydrogen production 0 electricity for synfuel production 0 final energy consumption (electricity) 987 fluctuating res (pv, wind, ocean) 8 share of fluctuating res 1% res share (domestic generation) 64%

2020 1,378 34 7 229 0 79 25 18 30 797 103 1 45 10 2 0 81 0 0 21 0 6 54 1 0

2025 1,517 32 5 221 0 59 15 11 42 799 192 17 95 14 30 1 114 0 0 29 0 3 78 4 0

2030 1,681 20 1 204 0 15 10 0 66 806 305 65 150 17 85 2 160 0 0 46 2 0 104 8 1

2040 2,235 1 0 107 0 2 2 0 122 814 568 200 313 31 255 20 288 0 0 93 5 0 148 39 7

2050 2,812 0 0 50 15 0 0 0 188 820 815 345 451 37 415 37 400 0 0 130 68 0 162 90 18

5 76 1,459 401 34 7 250 85 25 18 0 0 1,040 797 103 45 83 11 2 0 209 57 0 0 1,195 148 10% 71%

13 101 1,631 365 33 5 250 62 15 11 0 0 1,255 799 192 95 120 18 30 1 220 58 15 0 1,341 288 18% 77%

22 138 1,840 294 20 1 248 15 10 0 3 3 1,543 806 305 150 170 25 85 2 231 58 39 0 1,515 457 25% 84%

42 246 2,523 201 1 0 195 2 2 0 11 10 2,310 814 568 313 270 70 255 20 254 60 251 0 1,961 901 36% 92%

47 353 3,213 98 0 0 98 0 0 0 100 94 3,015 820 815 451 350 127 415 37 280 61 643 0 2,231 1,303 41% 97%

table 13.3.9 latin america: final energy consumption in transport pj/a 2012 2020 2025 road 6,326 7,326 7,177 fossil fuels 5,561 5,961 5,124 biofuels 557 1,052 1,281 synfuels 0 0 0 natural gas 207 293 574 hydrogen 0 0 36 electricity 0 20 162 rail 128 143 146 fossil fuels 109 118 93 biofuels 0 4 17 synfuels 0 0 0 electricity 18 21 35 navigation 122 164 188 fossil fuels 122 164 179 biofuels 0 0 9 synfuels 0 0 0 aviation 200 229 235 fossil fuels 200 229 228 biofuels 0 0 7 synfuels 0 0 0 total (incl. pipelines) 6,839 7,936 7,819 fossil fuels 5,993 6,472 5,624 biofuels (incl. biogas) 557 1,056 1,315 synfuels 0 0 0 natural gas 271 367 646 hydrogen 0 0 36 electricity 18 41 198 total res 569 1,085 1,495 res share 8% 14% 19%

2030 6,836 3,947 1,691 0 752 68 377 146 67 21 0 58 205 180 25 0 241 217 24 0 7,500 4,411 1,761 0 821 68 438 2,186 29%

2040 5,886 1,387 2,081 0 837 543 1,037 173 33 21 0 119 258 155 103 0 278 167 111 0 6,664 1,742 2,317 0 894 543 1,169 3,892 58%

2050 5,053 193 1,737 0 637 863 1,623 170 2 7 0 162 307 31 276 0 301 30 271 0 5,886 256 2,291 0 663 863 1,814 4,881 83%

table 13.3.10 latin america: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 134 60 74 0 0 7,354 4,221 2,241 22 0 0 870 0 7,487 4,281 2,314 22 0 0 870 0 39%

2020 3 0 2 0 0 228 78 142 8 0 8,535 4,559 2,589 301 6 76 1,005 0 8,766 4,637 2,733 301 14 76 1,005 0 44%

2025 9 1 6 1 1 380 103 245 31 1 8,149 3,549 2,825 514 26 118 1,116 0 8,538 3,653 3,076 515 59 118 1,116 1 54%

2030 22 2 15 3 2 595 148 365 70 13 8,344 3,005 2,980 825 55 169 1,310 0 8,961 3,154 3,359 828 127 169 1,310 13 63%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2040 78 2 49 16 12 1,389 310 676 345 58 7,923 1,485 2,831 1,364 150 352 1,740 0 9,390 1,796 3,557 1,380 507 352 1,740 58 79%

2050 109 0 49 38 22 2,532 226 1,172 785 349 6,660 393 2,513 1,358 176 491 1,719 9 9,301 619 3,734 1,396 983 491 1,719 359 93%

[r]evolution

table 13.3.10: latin america: installed capacity gw 2012 total generation 272 fossil 103 hard coal (& non-renewable waste) 6 lignite 2 gas (w/o h2) 54 oil 34 diesel 8 nuclear 3 hydrogen (fuel cells, gas power plants, gas chp) 0 renewables 166 hydro 148 wind 4 of which wind offshore 0 pv 0 biomass (& renewable waste) 14 geothermal 1 solar thermal power plants 0 ocean energy 0 fluctuating res (pv, wind, ocean) 4 share of fluctuating res 1% res share (domestic generation) 61%

2020 391 130 7 1 84 29 9 2 0 259 164 34 0 35 23 2 1 0 69 18% 66%

table 13.3.12: latin america: final energy demand pj/a 2012 2020 total (incl. non-energy use) 20,497 23,558 total energy use1 18,999 22,001 transport 6,839 7,936 oil products 5,993 6,472 natural gas 271 367 biofuels 557 1,056 synfuels 0 0 electricity 18 41 RES electricity 12 30 hydrogen 0 0 res share transport 8% 14% industry 6,962 8,254 electricity 1,569 1,903 RES electricity 1,012 1,356 public district heat 1 11 RES district heat 1 10 hard coal & lignite 373 611 oil products 1,627 1,326 gas 1,518 1,925 solar 0 169 biomass 1,874 2,270 geothermal 0 39 hydrogen 0 0 res share industry 41% 47% other sectors 5,198 5,812 electricity 1,967 2,359 RES electricity 1,269 1,682 public district heat 0 26 RES district heat 0 23 hard coal & lignite 3 6 oil products 1,269 1,149 gas 566 632 solar 22 132 biomass 1,370 1,488 geothermal 0 19 hydrogen 0 0 res share other sectors 51% 58% total res 6,117 8,275 res share 32% 38% non energy use 1,498 1,557 oil 969 866 gas 524 654 coal 5 37

2025 474 134 7 1 98 22 5 2 0 338 165 60 4 71 31 3 8 0 132 28% 71%

2025 23,070 21,545 7,819 5,624 646 1,315 0 198 153 36 19% 7,908 2,066 1,590 53 45 565 703 1,664 278 2,498 81 0 57% 5,817 2,563 1,972 41 35 5 815 619 236 1,509 29 0 65% 9,768 45% 1,526 803 656 67

2030 560 121 4 0 107 6 4 0 1 438 166 92 16 111 42 4 23 1 203 36% 78%

2030 22,974 21,464 7,500 4,411 821 1,761 0 438 368 68 29% 8,138 2,302 1,934 55 45 458 380 1,573 493 2,740 137 0 66% 5,827 2,715 2,281 99 82 4 616 624 332 1,398 39 0 71% 11,667 54% 1,510 749 664 97

2040 837 128 0 0 126 1 1 0 3 706 168 162 48 227 71 10 63 6 394 47% 84%

2040 21,497 20,018 6,664 1,742 894 2,317 0 1,169 1,076 543 58% 7,431 2,683 2,468 87 70 27 30 968 752 2,555 328 0 83% 5,923 3,206 2,949 225 181 0 194 574 612 1,031 81 0 82% 14,919 75% 1,479 645 680 154

2050 1,073 89 0 0 89 0 0 0 57 926 169 225 81 322 102 18 80 10 557 52% 86%

2050 19,382 17,903 5,886 256 663 2,291 0 1,814 1,756 863 83% 6,153 2,631 2,546 110 90 0 7 103 647 2,263 382 10 97% 5,864 3,587 3,471 231 189 0 22 439 711 712 162 0 89% 16,065 90% 1,479 578 710 191

1 excluding heat produced by chp autoproducers

table 13.3.13: latin america: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (578 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 248 34 10 101 67 37 15 1 0 10 4 263 35 10 111 107

2020 226 31 8 105 51 30 16 1 0 12 4 242 32 8 117 85

2025 182 30 5 93 38 16 19 1 0 16 2 201 30 5 110 56

2030 120 18 1 82 9 9 24 0 0 24 0 144 18 1 106 19

2040 46 1 0 42 2 2 45 0 0 45 0 91 1 0 87 3

2050 14 0 0 14 0 0 30 0 0 30 0 44 0 0 43 0

643 216 1,226 212% 262 130 470 248 116 485 2.5

604 166 1,216 210% 284 126 512 227 68 526 2.3

551 123 1,019 176% 216 101 463 184 54 549 1.9

489 78 812 141% 179 87 380 123 43 569 1.4

453 36 399 69% 92 53 181 54 19 601 0.7

446 14 138 24% 24 31 56 22 5 622 0.2

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.3.14: latin america: primary energy demand pj/a 2012 2020 total 27,122 30,641 fossil 18,956 19,721 hard coal (& non-renewable waste) 1,060 1,228 lignite 117 68 natural gas 5,802 6,797 crude oil 11,977 11,627 nuclear 245 191 renewables 7,921 10,729 hydro 2,601 2,869 wind 27 370 solar 22 469 biomass (& renewable waste) 5,139 6,674 geothermal 132 347 ocean energy 0 0 of which non-energy use 1,498 1,557 net electricity imports (final energy) 4 10 total res incl. net electricity import 7,924 10,737 res share 29% 35%

2025 29,876 17,041 1,290 48 6,487 9,217 123 12,712 2,877 691 965 7,654 521 4 1,526 10 12,714 43%

2030 29,664 14,293 906 9 6,582 6,796 0 15,370 2,903 1,098 1,674 8,983 704 7 1,510 10 15,373 52%

2040 28,892 8,452 197 0 5,476 2,780 0 20,439 2,932 2,045 3,425 10,219 1,746 72 1,479 10 20,450 71%

2050 27,392 3,888 191 0 2,817 881 0 23,504 2,951 2,935 4,514 10,113 2,858 133 1,479 10 23,514 86%

l at i n a m e r i ca : a d va n c e d e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.3.15 latin america: electricity generation twh/a 2012 1,152 31 7 198 0 121 29 22 10 722 8 0 0 4 0 0 63 1 0 16 0 6 40 0 0

2020 1,427 31 7 194 0 89 25 18 45 797 130 30 65 10 17 0 81 0 0 21 0 6 54 1 0

2025 1,666 23 5 183 0 59 15 11 62 799 275 85 125 14 85 10 114 0 0 29 0 3 78 4 0

2030 1,974 7 1 144 0 15 10 0 96 811 438 148 230 17 170 35 160 0 0 46 0 0 104 8 1

2040 2,929 0 0 67 8 4 1 0 154 817 940 430 446 64 376 60 288 0 0 93 11 0 146 41 7

2050 3,672 0 0 22 22 0 0 0 217 820 1,255 580 647 131 490 90 400 0 0 128 128 0 163 92 18

0 63 1,216 409 32 8 213 127 29 22 0 0 784 722 8 0 50 4 0 0 179 50 0 0 987 8 1% 64%

5 76 1,509 374 32 7 215 95 25 18 0 0 1,117 797 130 65 98 11 17 0 209 57 0 0 1,245 195 13% 74%

13 101 1,780 317 23 5 212 62 15 11 0 0 1,452 799 275 125 140 18 85 10 220 58 64 0 1,441 410 23% 82%

22 138 2,134 223 7 1 190 15 10 0 1 1 1,909 811 438 230 200 25 170 35 231 58 135 1 1,711 703 33% 90%

42 246 3,216 146 0 0 141 4 1 0 26 25 3,045 817 940 446 300 105 376 60 254 60 556 70 2,279 1,446 45% 95%

47 353 4,072 0 0 0 0 0 0 0 168 168 3,904 820 1,255 647 380 222 490 90 280 61 1,146 87 2,500 1,992 49% 100%

table 13.3.16 latin america: final energy consumption in transport pj/a 2012 2020 2025 road 6,326 7,052 6,580 fossil fuels 5,561 5,620 4,426 biofuels 557 992 1,106 synfuels 0 0 0 natural gas 207 273 444 hydrogen 0 0 156 electricity 0 168 448 rail 128 163 208 fossil fuels 109 108 80 biofuels 0 3 14 synfuels 0 0 0 electricity 18 51 114 navigation 122 164 188 fossil fuels 122 159 170 biofuels 0 5 19 synfuels 0 0 0 aviation 200 219 223 fossil fuels 200 213 201 biofuels 0 7 22 synfuels 0 0 0 total (incl. pipelines) 6,839 7,673 7,270 fossil fuels 5,993 6,100 4,876 biofuels (incl. biogas) 557 1,007 1,162 synfuels 0 0 0 natural gas 271 346 513 hydrogen 0 0 156 electricity 18 219 563 total res 569 1,169 1,748 res share 8% 15% 24%

2030 5,941 3,079 1,319 1 419 334 789 257 49 16 0 191 205 154 51 0 225 168 56 0 6,694 3,451 1,443 1 483 334 983 2,622 39%

2040 4,409 669 1,163 81 146 1,070 1,361 415 11 20 1 383 258 90 157 11 245 86 149 10 5,461 857 1,488 103 191 1,070 1,753 4,280 78%

2050 3,664 0 758 78 0 1,176 1,731 442 0 4 0 437 307 0 278 29 253 0 229 24 4,744 0 1,269 131 0 1,176 2,168 4,744 100%

table 13.3.17 latin america: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 134 60 74 0 0 7,354 4,221 2,241 22 0 0 870 0 7,487 4,281 2,314 22 0 0 870 0 39%

2020 3 0 2 0 0 227 78 141 8 0 8,536 4,560 2,589 301 6 76 1,005 0 8,766 4,638 2,732 301 14 76 1,005 0 44%

2025 9 1 6 1 1 385 104 248 32 1 8,145 3,549 2,825 514 26 118 1,112 0 8,538 3,654 3,079 515 59 118 1,112 1 55%

2030 22 2 15 3 2 602 155 370 70 7 8,337 3,005 2,980 825 55 169 1,304 0 8,961 3,162 3,365 828 127 169 1,304 7 63%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

326

2040 79 2 50 16 12 1,388 288 663 357 80 7,923 1,234 2,767 1,364 150 352 1,905 150 9,390 1,524 3,479 1,380 520 352 1,905 230 83%

2050 109 0 49 38 22 2,539 0 1,173 799 567 6,653 0 2,386 1,356 176 490 1,767 477 9,301 0 3,608 1,394 997 490 1,767 1,045 100%

table 13.3.18: latin america: installed capacity gw 2012 total generation 272 fossil 103 hard coal (& non-renewable waste) 6 lignite 2 gas (w/o h2) 54 oil 34 diesel 8 nuclear 3 hydrogen (fuel cells, gas power plants, gas chp) 0 renewables 166 hydro 148 wind 4 of which wind offshore 0 pv 0 biomass (& renewable waste) 14 geothermal 1 solar thermal power plants 0 ocean energy 0 fluctuating res (pv, wind, ocean) 4 share of fluctuating res 1% res share (domestic generation) 61%

2020 408 119 6 1 71 32 9 2 0 286 164 41 8 51 23 2 6 0 91 22% 70%

table 13.3.19: latin america: final energy demand pj/a 2012 2020 total (incl. non-energy use) 20,497 23,295 total energy use1 18,999 21,738 transport 6,839 7,673 oil products 5,993 6,100 natural gas 271 346 biofuels 557 1,007 synfuels 0 0 electricity 18 219 RES electricity 12 162 hydrogen 0 0 res share transport 8% 15% industry 6,962 8,254 electricity 1,569 1,903 RES electricity 1,012 1,409 public district heat 1 11 RES district heat 1 10 hard coal & lignite 373 611 oil products 1,627 1,326 gas 1,518 1,925 solar 0 169 biomass 1,874 2,270 geothermal 0 39 hydrogen 0 0 res share industry 41% 47% other sectors 5,198 5,812 electricity 1,967 2,359 RES electricity 1,269 1,748 public district heat 0 25 RES district heat 0 22 hard coal & lignite 3 7 oil products 1,269 1,149 gas 566 632 solar 22 132 biomass 1,370 1,488 geothermal 0 19 hydrogen 0 0 res share other sectors 51% 59% total res 6,117 8,476 res share 32% 39% non energy use 1,498 1,557 oil 969 866 gas 524 654 coal 5 37

2025 517 115 5 1 81 22 5 2 0 401 165 82 21 94 32 3 23 3 179 35% 77%

2025 22,521 20,995 7,270 4,876 513 1,162 0 563 459 156 24% 7,908 2,066 1,685 53 45 565 703 1,664 278 2,498 81 0 58% 5,817 2,559 2,087 45 39 6 815 619 236 1,509 29 0 67% 10,235 49% 1,526 803 656 67

2030 658 89 2 0 78 6 4 0 0 569 167 128 36 170 45 4 45 10 308 47% 86%

2030 22,290 20,780 6,694 3,451 483 1,443 1 983 880 334 39% 8,183 2,365 2,117 55 45 458 369 1,566 493 2,740 137 0 68% 5,903 2,813 2,519 106 87 4 598 613 332 1,398 39 0 74% 12,529 60% 1,510 749 664 97

2040 1,039 77 0 0 75 2 0 0 12 950 168 260 102 323 73 15 93 17 600 58% 91%

2040 20,556 19,077 5,461 857 191 1,488 103 1,753 1,673 1,070 78% 7,541 2,947 2,813 87 69 27 12 735 752 2,555 328 98 88% 6,075 3,503 3,342 225 180 0 155 484 612 951 81 64 86% 16,117 84% 1,479 645 680 154

2050 1,310 0 0 0 0 0 0 0 80 1,230 169 344 137 461 105 32 94 25 830 63% 94%

2050 18,623 17,144 4,744 0 0 1,269 131 2,168 2,168 1,176 100% 6,331 2,903 2,903 110 110 0 0 0 647 2,240 382 50 100% 6,070 3,929 3,929 230 230 0 0 0 709 586 162 453 100% 17,144 100% 1,479 578 710 191

1 excluding heat produced by chp autoproducers

table 13.3.20 latin america: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (578 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 248 34 10 101 67 37 15 1 0 10 4 263 35 10 111 107

2020 214 29 8 89 58 30 16 1 0 12 4 230 29 8 101 92

2025 157 21 5 77 38 16 19 1 0 16 2 176 21 5 94 56

2030 84 6 1 58 9 9 25 0 0 25 0 109 6 1 83 19

2040 26 0 0 23 2 1 42 0 0 42 0 68 0 0 65 3

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

643 216 1,226 212% 262 130 470 248 116 485 2.5

616 153 1,171 203% 284 126 482 215 64 526 2.2

555 99 923 160% 216 101 398 159 48 549 1.7

490 51 670 116% 178 85 288 88 30 569 1.2

468 21 234 41% 74 44 74 35 7 601 0.4

0 0 0 0% 0 0 0 0 0 622 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.3.21: latin america: primary energy demand pj/a 2012 2020 total 27,122 30,232 fossil 18,956 19,002 hard coal (& non-renewable waste) 1,060 1,155 lignite 117 68 natural gas 5,802 6,459 crude oil 11,977 11,320 nuclear 245 191 renewables 7,921 11,039 hydro 2,601 2,869 wind 27 468 solar 22 595 biomass (& renewable waste) 5,139 6,759 geothermal 132 347 ocean energy 0 0 of which non-energy use 1,498 1,557 net electricity imports (final energy) 4 10 total res incl. net electricity import 7,924 11,046 res share 29% 37%

2025 29,071 15,614 1,081 48 6,069 8,416 123 13,334 2,877 990 1,271 7,640 521 36 1,526 10 13,336 46%

2030 28,619 12,172 690 9 5,734 5,738 0 16,447 2,921 1,577 2,269 8,850 704 126 1,510 10 16,448 57%

2040 28,573 5,773 182 0 3,811 1,780 0 22,800 2,943 3,385 4,340 9,474 2,443 216 1,479 10 22,810 80%

2050 28,731 1,516 191 0 747 578 0 27,215 2,951 4,519 5,488 9,361 4,572 324 1,479 10 27,224 95%

energy

l at i n a m e r i ca : i n v e st m e n t a n d e m p loy m e n t table 13.3.22: latin america: investments in electricity generation unit 201220212031ref 2020 2030 2040 3fossil (w/o chp) billion $ 53.9 52.7 83.2 nuclear billion $ 8.3 9.2 7.8 chp (fossil + renewable) billion $ 22.3 27.8 11.8 renewables (w/o chp) billion $ 226.9 265.2 276.6 total billion $ 311.4 354.8 379.4 conventional (fossil & nuclear) billion $ 75.0 70.4 94.3 renewables billion $ 236.4 284.4 285.1 biomass billion $ 18.7 31.3 24.8 hydro billion $ 181.8 205.3 192.5 wind billion $ 21.0 26.0 36.6 pv billion $ 8.2 8.4 11.0 geothermal billion $ 6.6 8.3 9.2 solar thermal power plants billion $ 0.0 5.0 10.4 ocean energy billion $ 0.0 0.0 0.5 e[r] fossil (w/o chp) billion $ 41.0 21.4 36.6 nuclear billion $ 3.4 0.0 0.0 chp (fossil + renewable) billion $ 51.3 90.3 98.7 renewables (w/o chp) billion $ 242.1 454.3 746.1 total billion $ 337.8 566.0 881.3 conventional (fossil & nuclear) billion $ 71.7 53.8 77.2 renewables billion $ 266.1 512.2 804.2 biomass billion $ 34.3 76.4 99.1 hydro billion $ 105.7 66.2 69.1 wind billion $ 48.9 119.8 199.6 pv billion $ 61.4 100.7 153.4 geothermal billion $ 12.5 12.0 24.9 solar thermal power plants billion $ 3.4 134.4 240.3 ocean energy billion $ 0.0 2.6 17.7 adv e[r] fossil (w/o chp) billion $ 37.3 11.9 32.0 nuclear billion $ 3.4 0.0 0.0 chp (fossil + renewable) billion $ 31.6 84.1 75.0 renewables (w/o chp) billion $ 337.6 745.0 1,054.8 total billion $ 410.0 840.9 1,161.9 conventional (fossil & nuclear) billion $ 57.6 40.6 62.3 renewables billion $ 352.4 800.3 1,099.6 biomass billion $ 32.8 80.9 95.4 hydro billion $ 105.7 69.2 67.8 wind billion $ 77.4 190.1 367.2 pv billion $ 88.2 155.8 208.3 geothermal billion $ 12.5 12.0 52.7 solar thermal power plants billion $ 35.9 241.9 285.0 ocean energy billion $ 0.0 50.4 23.2

20412050 115.7 11.3 6.2 219.1 352.4 128.5 223.9 19.4 128.5 42.9 11.8 7.0 13.7 0.6

2012unit 2050 305.5 billion $/a 36.7 billion $/a 68.0 billion $/a 987.8 billion $/a 1,398.0 billion $/a 368.3 billion $/a 1,029.8 billion $/a 94.3 billion $/a 708.1 billion $/a 126.5 billion $/a 39.5 billion $/a 31.2 billion $/a 29.2 billion $/a 1.0 billion $/a

annual average

46.9 0.0 86.5 687.1 820.5 76.8 743.7 124.8 70.3 236.8 135.8 23.5 140.0 12.5

145.8 billion $/a 3.4 billion $/a 326.9 billion $/a 2,129.5 billion $/a 2,605.6 billion $/a 279.4 billion $/a 2,326.2 billion $/a 334.7 billion $/a 311.4 billion $/a 605.1 billion $/a 451.2 billion $/a 72.9 billion $/a 518.1 billion $/a 32.8 billion $/a

3.7 0.1 8.4 54.6 66.8 7.2 59.6 8.6 8.0 15.5 11.6 1.9 13.3 0.8

14.1 0.0 73.1 895.5 982.7 33.9 948.8 130.4 68.4 322.9 199.8 65.9 135.1 26.3

95.3 billion $/a 3.4 billion $/a 263.8 billion $/a 3,033.0 billion $/a 3,395.5 billion $/a 194.4 billion $/a 3,201.2 billion $/a 339.4 billion $/a 311.2 billion $/a 957.5 billion $/a 652.1 billion $/a 143.0 billion $/a 697.9 billion $/a 99.9 billion $/a

2.4 0.1 6.8 77.8 87.1 5.0 82.1 8.7 8.0 24.6 16.7 3.7 17.9 2.6

2012-2050 7.8 0.9 1.7 25.3 35.8 9.4 26.4 2.4 18.2 3.2 1.0 0.8 0.7 0.0

[r]evolution

table 13.3.23: latin america: investments in renewable heat generation unit 2012202120312041ref 2020 2030 2040 2050 heat pumps billion $ 0.0 0.0 0.0 0.0 deep geothermal billion $ 0.0 0.0 0.0 0.0 solar thermal billion $ 3.0 3.0 6.4 6.6 biomass billion $ 74.4 96.8 37.4 27.9 total billion $ 77.4 99.8 43.8 34.5 e[r] heat pumps billion $ 17.4 19.3 51.7 51.9 deep geothermal billion $ 1.4 10.1 23.9 13.9 solar thermal billion $ 40.1 68.1 88.9 13.4 bomass billion $ 92.3 85.9 2.1 0.5 total billion $ 151.3 183.4 166.5 79.6 adv e[r] heat pumps billion $ 17.4 19.3 51.7 51.8 deep geothermal billion $ 1.4 10.1 23.9 13.8 solar thermal billion $ 40.1 68.1 88.9 13.3 biomass billion $ 92.3 85.9 2.1 0.5 total billion $ 151.3 183.4 166.6 79.3

table 13.3.24: latin america: total employment in the energy sector

2012unit 2050 0.0 billion $/a 0.0 billion $/a 19.1 billion $/a 236.4 billion $/a 255.5 billion $/a

annual average

140.4 billion $/a 49.3 billion $/a 210.4 billion $/a 180.8 billion $/a 580.9 billion $/a

3.6 1.3 5.4 4.6 14.9

140.2 billion $/a 49.3 billion $/a 210.4 billion $/a 180.8 billion $/a 580.7 billion $/a

3.6 1.3 5.4 4.6 14.9

thousand jobs adv e [ r ] scenariO

reference scenariO

2012-2050 0.0 0.0 0.5 6.1 6.6

2015 224 99 284 790 45.9 29 1,472

2020 210 96 319 890 54.0 29 1,597

2025 206 97 351 987 58.9 27 1,727

2030 180 89 372 1,057 62.6 24 1,784

2020 485 230 434 891 32.6 438 2,510

2025 687 361 572 920 21.9 321 2,884

2030 769 552 717 962 11.3 411 3,423

88 418 9 958 584 299 19 26 2.3 0.3 28.9 1,472

81 483 10 1,024 629 303 25 33 3.0 1.6 1 28.8 1,597

89 530 10 1,098 678 320 31 35 2.9 3.2 0 27.3 1,727

109 544 11 1,120 718 303 32 33 2.8 6.1 1 24.2 1,784

34 422 4 2,050 766 103 207 414 6.2 84 32.6 388 49 2,510

27 367 5 2,485 899 122 267 651 7.5 165 52.6 289 33 2,884

13 312 7 3,092 998 113 511 750 20.8 254 33 375 36 3,423

327

oecd europe: reference scenario table 13.4.1 Oecd europe: electricity generation twh/a 2012 2,928 454 256 400 0 35 8 869 55 562 208 18 67 10 4 0 674 148 90 306 0 33 96 2 0

2020 3,237 415 249 475 0 12 7 852 83 591 407 49 124 13 10 1 697 137 87 326 0 19 126 2 0

2025 3,444 409 241 651 0 8 7 772 89 607 493 75 135 14 14 3 707 136 86 330 0 14 139 3 0

2030 3,650 406 232 823 0 6 7 692 96 624 580 101 146 16 18 5 717 131 84 339 0 7 152 3 0

2040 4,091 441 217 1,073 0 5 6 649 108 646 704 152 163 20 32 26 731 122 79 355 0 2 168 4 0

2050 4,414 488 181 1,212 0 2 6 606 117 669 828 203 182 25 49 48 746 103 75 375 0 0 186 6 0

477 197 3,602 1,729 601 346 706 68 8 869 0 0 1,004 562 208 67 151 12 4 0 248 281 0 0 3,067 275 8% 28%

496 201 3,935 1,727 552 336 800 31 7 852 0 0 1,356 591 407 124 209 15 10 1 275 245 0 0 3,401 532 14% 34%

504 203 4,151 1,881 544 326 981 22 7 772 0 0 1,498 607 493 135 228 17 14 3 292 244 0 0 3,601 631 15% 36%

511 205 4,366 2,035 537 316 1,162 13 7 692 0 0 1,639 624 580 146 248 19 18 5 308 242 0 0 3,802 731 17% 38%

522 209 4,822 2,301 564 296 1,428 7 6 649 0 0 1,872 646 704 163 275 25 32 26 341 253 0 0 4,212 894 19% 39%

532 214 5,160 2,443 591 256 1,587 2 6 606 0 0 2,111 669 828 182 303 31 49 48 366 263 0 0 4,515 1,059 21% 41%

table 13.4.2 Oecd europe: final energy consumption in transport pj/a 2012 2020 2025 road 12,527 12,572 12,545 fossil fuels 11,864 11,705 11,513 biofuels 606 747 858 synfuels 0 0 0 natural gas 56 92 116 hydrogen 0 0 0 electricity 2 28 57 rail 387 401 409 fossil fuels 149 149 149 biofuels 0 0 0 synfuels 0 0 0 electricity 238 253 260 navigation 238 300 331 fossil fuels 238 300 331 biofuels 0 0 0 synfuels 0 0 0 aviation 262 400 450 fossil fuels 262 400 450 biofuels 0 0 0 synfuels 0 0 0 total (incl. pipelines) 13,467 13,731 13,794 fossil fuels 12,512 12,554 12,443 biofuels (incl. biogas) 606 747 858 synfuels 0 0 0 natural gas 109 149 176 hydrogen 0 0 0 electricity 240 281 318 total res 672 844 972 res share 5% 6% 7%

2030 12,557 11,360 971 0 140 0 86 417 149 0 0 268 331 331 0 0 491 491 0 0 13,858 12,331 971 0 202 0 354 1,104 8%

2040 11,937 10,340 1,234 0 202 0 161 430 149 0 0 282 338 338 0 0 507 507 0 0 13,279 11,334 1,234 0 267 0 443 1,406 11%

2050 11,328 9,530 1,268 0 277 0 253 442 149 0 0 293 341 341 0 0 518 518 0 0 12,699 10,538 1,268 0 347 0 546 1,491 12%

table 13.4.3 Oecd europe: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 641 486 149 0 6 1,696 1,364 322 10 0 19,089 14,447 1,916 107 0 163 2,457 0 21,425 16,296 2,387 107 15 163 2,457 0 16%

2020 643 467 163 1 12 1,882 1,406 460 15 0 20,370 15,122 2,286 210 0 230 2,523 0 22,895 16,996 2,908 211 28 230 2,523 0 19%

2025 656 466 172 1 16 2,029 1,473 537 19 0 20,815 15,255 2,458 279 0 266 2,557 0 23,500 17,194 3,167 281 35 266 2,557 0 20%

2030 667 464 182 2 20 2,187 1,541 624 23 0 21,269 15,393 2,635 349 0 301 2,592 0 24,124 17,397 3,441 351 43 301 2,592 0 21%

2040 707 467 207 5 28 2,580 1,762 787 31 0 22,093 15,514 3,013 495 0 408 2,663 0 25,380 17,743 4,007 500 59 408 2,663 0 24%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

328

2050 670 416 209 11 33 3,324 2,176 1,108 40 0 22,979 15,645 3,400 674 0 546 2,714 0 26,973 18,237 4,717 685 74 546 2,714 0 27%

table 13.4.4: Oecd europe: installed capacity gw 2012 total generation 1,020 fossil 483 hard coal (& non-renewable waste) 117 lignite 67 gas (w/o h2) 240 oil 53 diesel 6 nuclear 127 hydrogen (fuel cells, gas power plants, gas chp) 0 renewables 409 hydro 202 wind 102 of which wind offshore 5 pv 68 biomass (& renewable waste) 33 geothermal 2 solar thermal power plants 2 ocean energy 0 fluctuating res (pv, wind, ocean) 170 share of fluctuating res 17% res share (domestic generation) 40% table 13.4.5: Oecd europe: final energy demand pj/a 2012 total (incl. non-energy use) 50,988 total energy use1 46,619 transport 13,467 oil products 12,512 natural gas 109 biofuels 606 synfuels 0 electricity 240 RES electricity 67 hydrogen 0 res share transport 5% industry 12,059 electricity 4,090 RES electricity 1,140 public district heat 677 RES district heat 68 hard coal & lignite 1,237 oil products 1,375 gas 3,900 solar 12 biomass 767 geothermal 2 hydrogen 0 res share industry 16% other sectors 21,092 electricity 6,710 RES electricity 1,870 public district heat 1,269 RES district heat 127 hard coal & lignite 860 oil products 3,233 gas 7,026 solar 95 biomass 1,790 geothermal 109 hydrogen 0 res share other sectors 19% total res 6,650 res share 14% non energy use 4,370 oil 3,844 gas 471 coal 55

2020 1,202 525 114 69 305 30 7 123 0 553 214 176 14 113 44 2 3 0 290 24% 46%

2020 53,477 49,210 13,731 12,554 149 747 0 281 97 0 6% 12,388 4,439 1,530 685 175 1,246 1,261 3,743 15 997 2 0 22% 23,092 7,523 2,594 1,390 356 827 3,046 7,946 195 2,005 158 0 23% 8,872 18% 4,267 3,753 460 54

2025 1,268 555 108 65 353 21 7 111 0 602 220 205 21 123 46 2 4 1 330 26% 47%

2025 54,372 50,247 13,794 12,443 176 858 0 318 115 0 7% 12,331 4,543 1,640 671 186 1,189 1,170 3,650 18 1,089 2 0 24% 24,122 8,104 2,925 1,512 419 828 2,760 8,381 262 2,090 186 0 24% 9,787 19% 4,125 3,629 445 52

2030 1,334 584 102 60 402 13 7 99 0 651 225 235 28 132 49 3 5 2 369 28% 49%

2040 1,454 637 102 54 466 8 7 91 0 727 232 273 41 145 53 3 9 11 429 29% 50%

2030 55,268 51,284 13,858 12,331 202 971 0 354 133 0 8% 12,274 4,648 1,745 657 195 1,131 1,078 3,556 20 1,180 2 0 26% 25,152 8,684 3,261 1,633 486 828 2,473 8,816 328 2,175 214 0 26% 10,711 21% 3,984 3,504 429 50

2040 56,140 52,544 13,279 11,334 267 1,234 0 443 172 0 11% 11,996 4,806 1,866 625 199 1,005 898 3,350 31 1,280 2 0 28% 27,269 9,915 3,850 1,900 604 834 1,936 9,495 464 2,428 297 0 28% 12,427 24% 3,596 3,163 388 45

2050 1,529 642 102 44 486 3 7 85 0 803 240 310 53 156 59 4 14 19 485 32% 52%

2050 56,709 53,500 12,699 10,538 347 1,268 0 546 223 0 12% 11,547 4,945 2,023 576 190 820 724 3,091 42 1,346 3 0 31% 29,254 10,765 4,403 2,199 725 839 1,499 10,212 632 2,701 407 0 30% 13,963 26% 3,209 2,823 346 41

1 excluding heat produced by chp autoproducers

table 13.4.6: Oecd europe: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (3,959 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 825 375 265 154 25 6 416 142 109 138 28 1,241 517 375 291 58

2020 768 330 237 187 9 5 403 135 107 145 16 1,171 466 343 331 30

2025 807 319 224 252 6 5 399 136 106 146 11 1,205 455 330 397 23

2030 849 312 213 316 4 5 392 133 104 148 6 1,241 445 317 464 15

2040 931 322 189 412 4 4 383 128 100 154 2 1,314 450 289 566 10

2050 953 344 152 451 2 4 369 111 96 162 0 1,322 455 248 613 6

718 345 3,723 94% 499 698 904 1,158 464 564 6.6

678 297 3,577 90% 483 731 909 1,088 367 580 6.2

641 290 3,550 90% 467 733 902 1,122 325 588 6.0

610 284 3,522 89% 450 736 895 1,157 283 594 5.9

571 272 3,431 87% 414 735 827 1,230 225 602 5.7

541 256 3,334 84% 367 742 774 1,242 209 604 5.5

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.4.7: Oecd europe: primary energy demand pj/a 2012 2020 total 72,959 74,667 fossil 54,561 53,678 hard coal (& non-renewable waste) 9,570 8,452 lignite 3,966 3,654 natural gas 17,462 19,049 crude oil 23,562 22,523 nuclear 9,613 9,295 renewables 8,785 11,694 hydro 2,023 2,126 wind 750 1,465 solar 409 694 biomass (& renewable waste) 5,093 6,806 geothermal 509 599 ocean energy 2 4 of which non-energy use 4,370 4,267 net electricity imports (final energy) -21 -49 total res incl. net electricity import 8,780 11,677 res share 12% 16%

2025 75,023 53,828 8,128 3,517 20,556 21,626 8,423 12,772 2,186 1,776 817 7,346 636 11 4,125 -50 12,754 17%

2030 75,406 53,989 7,818 3,384 22,069 20,718 7,551 13,867 2,245 2,087 940 7,885 691 18 3,984 -51 13,848 18%

2040 76,654 53,729 7,518 3,098 24,585 18,528 7,081 15,844 2,327 2,535 1,205 8,837 846 95 3,596 -55 15,823 21%

2050 75,945 51,782 7,236 2,694 25,356 16,496 6,616 17,547 2,408 2,983 1,520 9,436 1,027 173 3,209 -55 17,525 23%

energy

o e c d e u r o p e : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.4.8 Oecd europe: electricity generation twh/a 2012 2,928 454 256 400 0 35 8 869 55 562 208 18 67 10 4 0 674 148 90 306 0 33 96 2 0

2020 2,999 327 183 540 0 3 7 560 100 591 479 58 183 12 12 2 721 104 67 350 0 24 171 5 0

2025 2,954 251 59 554 0 0 6 360 102 596 682 121 276 24 31 12 763 64 26 371 0 7 278 15 0

2030 3,004 216 22 554 0 0 5 80 100 600 915 211 376 39 68 30 805 36 3 376 0 0 351 39 0

2040 3,384 44 0 343 0 0 3 0 90 610 1,349 431 577 70 208 90 790 0 0 307 9 0 366 111 6

2050 3,694 4 0 56 0 0 1 0 79 620 1,592 563 723 161 327 130 710 0 0 183 26 0 351 149 27

477 197 3,602 1,729 601 346 706 68 8 869 0 0 1,004 562 208 67 151 12 4 0 248 281 0 0 3,067 275 8% 28%

510 211 3,720 1,605 431 250 890 27 7 560 0 0 1,555 591 479 183 272 17 12 2 255 240 2 0 3,238 664 18% 42%

525 238 3,716 1,339 315 85 925 8 6 360 0 0 2,017 596 682 276 380 39 31 12 245 228 35 0 3,252 970 26% 54%

540 265 3,809 1,212 252 25 930 0 5 80 0 0 2,517 600 915 376 451 77 68 30 240 217 146 0 3,340 1,321 35% 66%

515 275 4,174 688 44 0 641 0 3 0 15 13 3,470 610 1,349 577 456 180 208 90 230 173 606 0 3,465 2,016 48% 83%

460 250 4,404 219 4 0 214 0 1 0 53 50 4,132 620 1,592 723 430 309 327 130 230 134 1,016 0 3,424 2,446 56% 95%

table 13.4.9 Oecd europe: final energy consumption in transport pj/a 2012 2020 2025 road 12,527 11,069 9,519 fossil fuels 11,864 10,221 8,405 biofuels 606 618 584 synfuels 0 0 0 natural gas 56 111 143 hydrogen 0 5 86 electricity 2 114 301 rail 387 407 412 fossil fuels 149 133 114 biofuels 0 7 6 synfuels 0 0 0 electricity 238 267 292 navigation 238 290 284 fossil fuels 238 276 269 biofuels 0 15 14 synfuels 0 0 0 aviation 262 380 400 fossil fuels 262 380 389 biofuels 0 0 11 synfuels 0 0 0 total (incl. pipelines) 13,467 12,196 10,660 fossil fuels 12,512 11,009 9,177 biofuels (incl. biogas) 606 639 616 synfuels 0 0 0 natural gas 109 161 187 hydrogen 0 5 86 electricity 240 381 594 total res 672 801 985 res share 5% 7% 9%

2030 8,157 6,376 517 0 150 370 744 417 81 19 0 317 265 241 24 0 410 385 25 0 9,289 7,084 585 0 189 370 1,062 1,531 16%

2040 5,690 2,025 415 0 164 1,389 1,697 434 48 19 0 367 247 198 49 0 390 312 78 0 6,792 2,583 561 0 189 1,389 2,070 3,448 51%

2050 4,925 554 321 0 177 1,885 1,987 446 19 10 0 417 240 156 84 0 370 240 130 0 6,000 969 544 0 186 1,885 2,415 4,628 77%

table 13.4.10 Oecd europe: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 641 486 149 0 6 1,696 1,364 322 10 0 19,089 14,447 1,916 107 0 163 2,457 0 21,425 16,296 2,387 107 15 163 2,457 0 16%

2020 645 429 190 6 19 1,962 1,311 618 33 0 18,537 13,132 2,128 355 0 435 2,487 0 21,144 14,872 2,937 362 52 435 2,487 0 23%

2025 807 337 242 145 83 2,370 1,176 1,087 107 0 17,477 11,044 2,119 1,004 0 840 2,471 0 20,654 12,556 3,448 1,149 190 840 2,471 0 34%

2030 859 262 245 219 133 2,756 1,049 1,426 278 3 16,505 8,984 2,041 1,597 0 1,459 2,424 0 20,120 10,295 3,712 1,816 411 1,459 2,424 3 45%

2040 1,244 119 261 585 279 3,358 801 1,645 837 75 14,684 5,139 1,864 2,476 0 2,902 2,247 58 19,287 6,059 3,770 3,061 1,116 2,902 2,247 132 67%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2050 1,464 59 249 849 307 3,885 519 1,934 1,156 276 12,797 1,919 1,691 2,963 0 3,617 2,256 351 18,145 2,496 3,874 3,811 1,463 3,617 2,256 627 86%

[r]evolution

table 13.4.10: Oecd europe: installed capacity gw 2012 total generation 1,020 fossil 483 hard coal (& non-renewable waste) 117 lignite 67 gas (w/o h2) 240 oil 53 diesel 6 nuclear 127 hydrogen (fuel cells, gas power plants, gas chp) 0 renewables 409 hydro 202 wind 102 of which wind offshore 5 pv 68 biomass (& renewable waste) 33 geothermal 2 solar thermal power plants 2 ocean energy 0 fluctuating res (pv, wind, ocean) 170 share of fluctuating res 17% res share (domestic generation) 40%

2020 1,220 487 89 51 313 26 7 81 0 653 214 207 16 168 57 2 4 1 376 31% 53%

table 13.4.12: Oecd europe: final energy demand pj/a 2012 2020 total (incl. non-energy use) 50,988 49,081 total energy use1 46,619 44,814 transport 13,467 12,196 oil products 12,512 11,009 natural gas 109 161 biofuels 606 639 synfuels 0 0 electricity 240 381 RES electricity 67 159 hydrogen 0 5 res share transport 5% 7% industry 12,059 11,880 electricity 4,090 4,241 RES electricity 1,140 1,773 public district heat 677 729 RES district heat 140 248 hard coal & lignite 1,237 1,035 oil products 1,375 1,011 gas 3,900 3,767 solar 12 87 biomass 767 959 geothermal 2 51 hydrogen 0 0 res share industry 17% 26% other sectors 21,092 20,739 electricity 6,710 7,033 RES electricity 1,870 2,940 public district heat 1,269 1,420 RES district heat 262 482 hard coal & lignite 860 561 oil products 3,233 2,676 gas 7,026 6,692 solar 95 268 biomass 1,790 1,836 geothermal 109 252 hydrogen 0 0 res share other sectors 20% 28% total res 6,857 9,698 res share 15% 22% non energy use 4,370 4,267 oil 3,844 3,571 gas 471 500 coal 55 196

2025 1,288 392 63 17 299 7 6 52 0 844 216 281 34 252 77 5 8 5 538 42% 66%

2025 45,889 41,764 10,660 9,177 187 616 0 594 322 86 9% 11,350 4,196 2,277 797 430 605 574 3,780 292 1,016 91 0 36% 19,754 6,918 3,755 1,787 964 180 1,751 6,178 712 1,724 503 0 39% 12,749 31% 4,125 3,333 504 289

2030 1,434 369 50 5 309 0 5 11 0 1,053 216 363 59 341 95 10 16 12 716 50% 73%

2040 1,731 293 9 0 281 0 3 0 6 1,432 219 502 117 513 97 24 43 34 1,049 61% 83%

2030 42,821 38,837 9,289 7,084 189 585 0 1,062 702 370 16% 10,784 4,209 2,781 908 593 332 295 3,397 475 970 197 0 47% 18,764 6,753 4,461 1,932 1,261 0 1,181 5,300 1,122 1,629 848 0 50% 15,868 41% 3,984 3,091 514 378

2040 37,012 33,416 6,792 2,583 189 561 0 2,070 1,727 1,389 51% 9,660 4,204 3,509 1,004 821 153 105 2,058 736 869 469 62 67% 16,963 6,201 5,175 2,308 1,886 0 382 3,248 1,740 1,425 1,659 0 70% 21,787 65% 3,596 2,521 500 575

2050 1,848 164 1 0 162 0 1 0 20 1,664 223 570 148 620 100 41 65 45 1,235 67% 90%

2050 32,989 29,780 6,000 969 186 544 0 2,415 2,293 1,885 77% 8,758 4,133 3,925 955 858 48 14 1,053 874 832 481 369 84% 15,022 5,778 5,487 2,517 2,261 0 49 1,176 2,089 1,181 2,233 0 88% 25,197 85% 3,209 2,057 511 642

1 excluding heat produced by chp autoproducers

table 13.4.13: Oecd europe: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (3,959 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 825 375 265 154 25 6 416 142 109 138 28 1,241 517 375 291 58

2020 654 261 174 212 2 5 359 101 82 155 20 1,013 361 257 368 27

2025 470 196 55 214 0 4 264 63 33 163 6 734 259 87 377 11

2030 402 166 20 212 0 3 202 35 3 163 0 605 201 24 376 4

2040 166 32 0 132 0 2 128 0 0 128 0 294 32 0 260 2

2050 25 3 0 21 0 1 67 0 0 67 0 91 3 0 88 1

718 345 3,723 94% 499 698 904 1,158 464 564 6.6

631 272 3,124 79% 442 612 799 934 337 580 5.4

548 198 2,429 61% 368 482 668 659 252 588 4.1

499 159 1,906 48% 297 377 518 534 180 594 3.2

427 70 899 23% 181 209 195 239 76 602 1.5

417 21 329 8% 82 72 79 66 29 604 0.5

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.4.14: Oecd europe: primary energy demand pj/a 2012 2020 total 72,959 66,893 fossil 54,561 48,117 hard coal (& non-renewable waste) 9,570 6,756 lignite 3,966 2,708 natural gas 17,462 18,731 crude oil 23,562 19,922 nuclear 9,613 6,112 renewables 8,785 12,664 hydro 2,023 2,126 wind 750 1,723 solar 409 1,066 biomass (& renewable waste) 5,093 6,937 geothermal 509 805 ocean energy 2 7 of which non-energy use 4,370 4,267 net electricity imports (final energy) -21 54 total res incl. net electricity import 8,780 12,687 res share 12% 19%

2025 60,323 39,849 4,384 952 18,640 15,874 3,930 16,544 2,146 2,455 2,257 7,946 1,698 43 4,125 160 16,576 27%

2030 54,162 33,008 3,264 228 17,228 12,287 873 20,281 2,160 3,294 3,414 8,305 3,000 108 3,984 482 20,337 37%

2040 45,874 18,353 1,130 0 11,378 5,845 0 27,520 2,196 4,858 5,886 8,035 6,222 324 3,596 1,080 28,359 60%

2050 41,009 8,556 729 0 4,662 3,165 0 32,453 2,232 5,733 7,593 7,529 8,898 468 3,209 1,440 33,721 79%

o e c d e u r o p e : a d va n c e d e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.4.15 Oecd europe: electricity generation twh/a 2012 power plants 2,928 hard coal (& non-renewable waste) 454 lignite 256 gas 400 of which from H2 0 oil 35 diesel 8 nuclear 869 biomass (& renewable waste) 55 hydro 562 wind 208 of which wind offshore 18 pv 67 geothermal 10 solar thermal power plants 4 ocean energy 0 combined heat and power plants 674 hard coal (& non-renewable waste) 148 lignite 90 gas 306 of which from H2 0 oil 33 biomass (& renewable waste) 96 geothermal 2 hydrogen 0 CHP by producer main activity producers 477 autoproducers 197 total generation 3,602 fossil 1,729 hard coal (& non-renewable waste) 601 lignite 346 gas 706 oil 68 diesel 8 nuclear 869 hydrogen 0 of which renewable H2 0 renewables (w/o renewable hydrogen) 1,004 hydro 562 wind 208 pv 67 biomass (& renewable waste) 151 geothermal 12 solar thermal power plants 4 ocean energy 0 distribution losses 248 own consumption electricity 281 electricity for hydrogen production 0 electricity for synfuel production 0 final energy consumption (electricity) 3,067 fluctuating res (pv, wind, ocean) 275 share of fluctuating res 8% res share (domestic generation) 28%

2020 3,028 323 183 540 0 3 7 560 120 591 485 60 188 13 13 2 721 104 67 350 0 24 171 5 0

2025 3,088 248 59 554 3 0 6 360 122 596 736 150 325 33 36 14 763 64 26 371 2 7 278 15 0

2030 3,346 199 22 554 11 0 5 80 120 600 1,068 294 468 66 128 35 805 36 3 376 8 0 351 39 0

2040 4,183 13 0 283 40 0 3 0 120 610 1,822 625 760 144 318 110 790 0 0 307 43 0 366 111 6

2050 5,054 0 0 70 70 0 0 0 102 620 2,351 901 1,080 241 430 160 710 0 0 170 170 0 365 149 27

510 211 3,749 1,601 427 250 890 27 7 560 0 0 1,588 591 485 188 292 18 13 2 255 240 18 0 3,250 675 18% 42%

525 238 3,851 1,331 312 85 920 8 6 360 5 3 2,155 596 736 325 400 48 36 14 245 228 93 21 3,309 1,075 28% 56%

540 265 4,151 1,177 235 25 911 0 5 80 19 13 2,875 600 1,068 468 471 104 128 35 240 217 295 37 3,515 1,571 38% 70%

515 275 4,973 524 13 0 507 0 3 0 89 80 4,360 610 1,822 760 486 255 318 110 230 173 1,022 90 3,859 2,692 54% 89%

460 250 5,764 0 0 0 0 0 0 0 267 267 5,498 620 2,351 1,080 467 390 430 160 230 134 1,924 207 3,889 3,591 62% 100%

table 13.4.16 Oecd europe: final energy consumption in transport pj/a 2012 2020 2025 road 12,527 10,985 9,099 fossil fuels 11,864 10,080 7,823 biofuels 606 618 602 synfuels 0 0 28 natural gas 56 109 122 hydrogen 0 45 147 electricity 2 132 404 rail 387 422 494 fossil fuels 149 122 93 biofuels 0 6 9 synfuels 0 0 0 electricity 238 294 392 navigation 238 290 284 fossil fuels 238 276 281 biofuels 0 15 3 synfuels 0 0 0 aviation 262 376 388 fossil fuels 262 376 386 biofuels 0 0 2 synfuels 0 0 0 total (incl. pipelines) 13,467 12,123 10,336 fossil fuels 12,512 10,854 8,583 biofuels (incl. biogas) 606 639 616 synfuels 0 0 28 natural gas 109 158 165 hydrogen 0 45 147 electricity 240 426 797 total res 672 839 1,161 res share 5% 7% 11%

2030 7,406 5,468 496 45 98 450 894 570 64 10 1 495 265 229 33 3 385 335 46 4 8,710 6,096 585 53 134 450 1,392 1,903 22%

2040 4,404 917 382 90 27 1,383 1,695 743 24 13 3 703 247 161 70 17 339 221 96 23 5,851 1,322 561 133 43 1,383 2,409 4,065 69%

2050 3,505 0 194 112 0 1,611 1,700 866 0 9 5 852 240 0 152 87 296 0 188 108 5,034 0 544 312 0 1,611 2,567 5,034 100%

table 13.4.17 Oecd europe: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 641 486 149 0 6 1,696 1,364 322 10 0 19,089 14,447 1,916 107 0 163 2,457 0 21,425 16,296 2,387 107 15 163 2,457 0 16%

2020 645 429 190 6 19 1,962 1,311 618 33 0 18,537 13,132 2,128 355 0 435 2,487 0 21,144 14,872 2,937 362 52 435 2,487 0 23%

2025 807 337 242 145 83 2,370 1,171 1,087 107 4 17,477 11,000 2,119 1,004 0 840 2,471 43 20,654 12,509 3,448 1,149 190 840 2,471 48 35%

2030 859 262 245 219 133 2,756 1,031 1,426 278 21 16,505 8,831 2,041 1,597 0 1,459 2,424 153 20,120 10,124 3,712 1,816 411 1,459 2,424 174 46%

2040 1,244 119 261 585 279 3,358 713 1,645 837 163 14,684 4,057 1,864 2,624 0 2,992 2,555 593 19,287 4,889 3,770 3,209 1,116 2,992 2,555 756 73%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

330

2050 1,436 0 244 833 359 3,913 0 2,005 1,156 752 12,797 0 1,691 3,184 0 3,786 2,605 1,531 18,145 0 3,940 4,016 1,515 3,786 2,605 2,283 100%

table 13.4.18: Oecd europe: installed capacity gw 2012 total generation 1,020 fossil 483 hard coal (& non-renewable waste) 117 lignite 67 gas (w/o h2) 240 oil 53 diesel 6 nuclear 127 hydrogen (fuel cells, gas power plants, gas chp) 0 renewables 409 hydro 202 wind 102 of which wind offshore 5 pv 68 biomass (& renewable waste) 33 geothermal 2 solar thermal power plants 2 ocean energy 0 fluctuating res (pv, wind, ocean) 170 share of fluctuating res 17% res share (domestic generation) 40%

2020 1,203 458 88 51 286 26 7 81 0 664 214 210 17 173 61 2 4 1 383 32% 55%

table 13.4.19: Oecd europe: final energy demand pj/a 2012 2020 total (incl. non-energy use) 50,988 49,008 total energy use1 46,619 44,742 transport 13,467 12,123 oil products 12,512 10,854 natural gas 109 158 biofuels 606 639 synfuels 0 0 electricity 240 426 RES electricity 67 181 hydrogen 0 45 res share transport 5% 7% industry 12,059 11,880 electricity 4,090 4,241 RES electricity 1,140 1,797 public district heat 677 729 RES district heat 140 248 hard coal & lignite 1,237 1,035 oil products 1,375 1,011 gas 3,900 3,767 solar 12 87 biomass 767 959 geothermal 2 51 hydrogen 0 0 res share industry 17% 26% other sectors 21,092 20,739 electricity 6,710 7,033 RES electricity 1,870 2,980 public district heat 1,269 1,420 RES district heat 262 482 hard coal & lignite 860 561 oil products 3,233 2,676 gas 7,026 6,692 solar 95 268 biomass 1,790 1,836 geothermal 109 252 hydrogen 0 0 res share other sectors 20% 28% total res 6,857 9,799 res share 15% 22% non energy use 4,370 4,267 oil 3,844 3,571 gas 471 500 coal 55 196

2025 1,349 380 62 17 288 7 6 52 1 915 216 300 42 297 81 6 10 6 603 45% 68%

2025 45,565 41,440 10,336 8,583 165 616 28 797 447 147 11% 11,350 4,196 2,351 797 430 605 574 3,761 292 1,016 91 19 37% 19,754 6,918 3,877 1,787 965 180 1,751 6,148 712 1,724 503 30 39% 13,150 32% 4,125 3,333 504 289

2030 1,577 344 47 5 287 0 5 11 6 1,216 216 416 82 425 100 14 30 14 856 54% 77%

2040 2,066 217 3 0 211 0 3 0 36 1,813 219 672 169 675 105 34 66 42 1,388 67% 88%

2030 42,458 38,475 8,710 6,096 134 585 53 1,392 969 450 22% 10,826 4,268 2,970 908 596 332 285 3,323 475 970 197 67 49% 18,939 6,995 4,867 1,932 1,267 0 1,140 5,170 1,122 1,629 848 104 52% 16,962 44% 3,984 3,091 514 378

2040 36,562 32,966 5,851 1,322 43 561 133 2,409 2,151 1,383 69% 9,758 4,444 3,967 1,004 834 137 88 1,684 768 869 493 271 74% 17,357 7,038 6,284 2,308 1,916 0 317 2,341 1,856 1,425 1,702 370 78% 24,750 75% 3,596 2,521 500 575

2050 2,460 0 0 0 0 0 0 0 181 2,279 223 831 237 926 108 52 85 53 1,811 74% 93%

2050 32,798 29,589 5,034 0 0 544 312 2,567 2,567 1,611 100% 8,911 4,548 4,548 955 955 0 0 0 990 832 568 1,018 100% 15,644 6,887 6,887 2,517 2,517 0 0 0 2,193 1,181 2,272 594 100% 29,589 100% 3,209 2,057 511 642

1 excluding heat produced by chp autoproducers

table 13.4.20 Oecd europe: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (3,959 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 825 375 265 154 25 6 416 142 109 138 28 1,241 517 375 291 58

2020 651 257 174 212 2 5 359 101 82 155 20 1,009 358 257 368 27

2025 466 194 55 213 0 4 264 63 33 162 6 729 257 87 375 11

2030 385 153 20 208 0 3 199 35 3 160 0 584 188 24 368 4

2040 105 10 0 94 0 2 113 0 0 113 0 219 10 0 207 2

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

718 345 3,723 94% 499 698 904 1,158 464 564 6.6

631 269 3,107 78% 442 612 787 931 335 580 5.4

548 189 2,373 60% 367 481 625 655 246 588 4.0

496 141 1,731 44% 292 367 444 514 114 594 2.9

418 44 598 15% 151 154 97 171 25 602 1.0

0 0 0 0% 0 0 0 0 0 604 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.4.21: Oecd europe: primary energy demand pj/a 2012 2020 total 72,959 66,873 fossil 54,561 47,854 hard coal (& non-renewable waste) 9,570 6,512 lignite 3,966 2,708 natural gas 17,462 18,880 crude oil 23,562 19,754 nuclear 9,613 6,112 renewables 8,785 12,907 hydro 2,023 2,126 wind 750 1,745 solar 409 1,087 biomass (& renewable waste) 5,093 7,108 geothermal 509 833 ocean energy 2 7 of which non-energy use 4,370 4,267 net electricity imports (final energy) -21 54 total res incl. net electricity import 8,780 12,930 res share 12% 19%

2025 60,280 39,036 4,176 952 18,674 15,234 3,930 17,314 2,146 2,650 2,451 8,113 1,905 50 4,125 160 17,346 29%

2030 54,370 31,322 2,945 228 16,970 11,178 873 22,175 2,160 3,845 3,964 8,465 3,614 126 3,984 554 22,226 40%

2040 46,451 14,132 828 0 8,900 4,404 0 32,319 2,196 6,562 7,088 8,305 7,773 396 3,596 1,440 33,393 70%

2050 42,392 3,214 642 0 516 2,057 0 39,178 2,232 8,464 9,453 7,874 10,579 576 3,209 2,232 41,120 92%

energy

o e c d e u r o p e : i n v e st m e n t a n d e m p loy m e n t table 13.4.22: Oecd europe: investments in electricity generation unit 201220212031ref 2020 2030 2040 fossil (w/o chp) billion $ 177.1 187.9 202.1 nuclear billion $ 135.6 17.1 79.8 chp (fossil + renewable) billion $ 190.8 133.8 73.9 renewables (w/o chp) billion $ 520.5 461.4 632.2 total billion $ 1,024.0 800.2 988.0 conventional (fossil & nuclear) billion $ 458.6 285.2 311.4 renewables billion $ 565.4 515.0 676.6 biomass billion $ 63.8 71.3 68.2 hydro billion $ 128.8 133.9 126.5 wind billion $ 208.7 228.8 296.1 pv billion $ 138.4 52.4 109.9 geothermal billion $ 9.9 8.2 11.2 solar thermal power plants billion $ 13.9 11.8 33.4 ocean energy billion $ 1.9 8.6 31.1 e[r] fossil (w/o chp) billion $ 148.9 81.3 66.8 nuclear billion $ 61.1 0.0 0.0 chp (fossil + renewable) billion $ 224.4 259.6 195.3 renewables (w/o chp) billion $ 685.0 994.7 1,323.5 total billion $ 1,119.4 1,335.5 1,585.6 conventional (fossil & nuclear) billion $ 349.0 137.6 110.2 renewables billion $ 770.4 1,197.9 1,475.4 biomass billion $ 108.1 184.3 102.8 hydro billion $ 128.8 105.5 110.9 wind billion $ 268.2 448.2 590.0 pv billion $ 232.2 257.4 326.2 geothermal billion $ 13.3 73.5 111.5 solar thermal power plants billion $ 15.4 71.3 153.8 ocean energy billion $ 4.3 57.7 80.3 adv e[r] fossil (w/o chp) billion $ 126.4 85.5 56.0 nuclear billion $ 61.1 0.0 0.0 chp (fossil + renewable) billion $ 224.4 259.6 195.3 renewables (w/o chp) billion $ 711.2 1,347.5 1,767.3 total billion $ 1,123.1 1,692.6 2,018.6 conventional (fossil & nuclear) billion $ 326.5 141.9 99.4 renewables billion $ 796.6 1,550.7 1,919.3 biomass billion $ 117.8 186.1 118.9 hydro billion $ 128.8 105.5 110.9 wind billion $ 273.7 579.2 833.0 pv billion $ 240.1 363.8 410.6 geothermal billion $ 14.7 99.4 148.0 solar thermal power plants billion $ 17.1 148.7 199.3 ocean energy billion $ 4.3 68.0 98.6

20412050 243.1 77.7 27.0 537.2 884.9 321.1 563.8 47.1 134.0 280.5 39.8 8.7 32.9 20.8

2012unit 2050 810.2 billion $/a 310.1 billion $/a 425.5 billion $/a 2,151.3 billion $/a 3,697.1 billion $/a 1,376.4 billion $/a 2,320.8 billion $/a 250.4 billion $/a 523.2 billion $/a 1,014.1 billion $/a 340.6 billion $/a 38.0 billion $/a 92.0 billion $/a 62.4 billion $/a

annual average

96.6 0.0 179.0 1,174.6 1,450.2 96.6 1,353.6 140.4 117.8 546.8 240.2 135.6 138.7 34.1

393.7 billion $/a 61.1 billion $/a 858.2 billion $/a 4,177.7 billion $/a 5,490.7 billion $/a 693.5 billion $/a 4,797.2 billion $/a 535.6 billion $/a 462.9 billion $/a 1,853.2 billion $/a 1,056.0 billion $/a 333.9 billion $/a 379.2 billion $/a 176.4 billion $/a

10.1 1.6 22.0 107.1 140.8 17.8 123.0 13.7 11.9 47.5 27.1 8.6 9.7 4.5

112.0 0.0 188.9 1,649.9 1,950.9 112.0 1,838.9 146.8 117.8 850.1 413.3 144.1 128.1 38.7

380.0 billion $/a 61.1 billion $/a 868.1 billion $/a 5,476.0 billion $/a 6,785.2 billion $/a 679.8 billion $/a 6,105.4 billion $/a 569.6 billion $/a 462.9 billion $/a 2,536.0 billion $/a 1,427.9 billion $/a 406.1 billion $/a 493.3 billion $/a 209.6 billion $/a

9.7 1.6 22.3 140.4 174.0 17.4 156.5 14.6 11.9 65.0 36.6 10.4 12.6 5.4

2012-2050 20.8 8.0 10.9 55.2 94.8 35.3 59.5 6.4 13.4 26.0 8.7 1.0 2.4 1.6

[r]evolution

table 13.4.23: Oecd europe: investments in renewable heat generation unit 2012202120312041ref 2020 2030 2040 2050 heat pumps billion $ 46.8 46.2 55.0 60.1 deep geothermal billion $ 6.2 0.5 10.0 6.1 solar thermal billion $ 47.3 50.3 71.0 71.0 biomass billion $ 169.2 200.1 81.2 71.7 total billion $ 269.5 297.1 217.2 208.9 e[r] heat pumps billion $ 104.0 319.8 454.9 460.6 deep geothermal billion $ 10.8 8.2 88.7 37.6 solar thermal billion $ 91.4 376.1 328.0 424.0 bomass billion $ 89.8 22.1 3.0 0.0 total billion $ 296.0 726.2 874.6 922.1 adv e[r] heat pumps billion $ 104.0 319.8 477.0 479.0 deep geothermal billion $ 10.8 8.2 88.7 93.6 solar thermal billion $ 91.4 376.1 364.4 437.0 biomass billion $ 89.8 22.1 3.0 0.3 total billion $ 296.0 726.2 933.1 1,009.9

table 13.4.24: Oecd europe: total employment in the energy sector

2012unit 2050 208.0 billion $/a 22.8 billion $/a 239.7 billion $/a 522.2 billion $/a 992.7 billion $/a

annual average

1,339.2 billion $/a 145.3 billion $/a 1,219.4 billion $/a 114.9 billion $/a 2,818.9 billion $/a

34.3 3.7 31.3 2.9 72.3

1,379.7 billion $/a 201.3 billion $/a 1,269.0 billion $/a 115.2 billion $/a 2,965.2 billion $/a

35.4 5.2 32.5 3.0 76.0

thousand jobs adv e [ r ] scenariO

reference scenariO

2012-2050 5.3 0.6 6.1 13.4 25.5

2015 138 119 380 551 89 1,278

2020 83 75 402 526 59 1,145

2025 90 72 405 514 71 1,152

2030 85 58 407 502 68 1,120

2020 388 437 443 540 243 2,051

2025 458 516 535 513 753 2,774

2030 442 533 623 475 691 2,764

294 175 84 725 276 60 129 164 1.8 5.5 0.6 74 14.7 1,278

253 178 82 631 296 57 116 93 1.6 6.5 2.3 48 10.7 1,145

228 180 81 662 313 59 122 86 1.5 7.2 2.7 60 10.2 1,152

209 176 80 654 328 58 110 70 1.4 10.0 8.7 59 9.6 1,120

246 162 96 1,547 391 48 341 468 10 29 16.6 186 57 2,051

177 166 101 2,330 459 48 434 517 15 71 32 636 117 2,774

135 157 110 2,363 455 51 486 512 20 102 46 544 146 2,764

331

a f r i ca : r e f e r e n c e s c e n a r i o table 13.5.4: africa: installed capacity gw

table 13.5.1 africa: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share (domestic generation)

2012 716 256 0 256 0 68 5 13 2 112 2 0 0 2 0 0 0 0 0 0 0 0 0 0 0

2020 1,014 314 0 384 0 86 7 13 9 167 13 0 10 8 3 0 3 1 0 1 0 0 1 0 0

2025 1,237 352 0 482 0 79 9 19 16 212 22 0 22 16 8 0 8 4 0 3 0 0 2 0 0

2030 1,457 389 0 579 0 71 11 25 23 258 30 1 34 23 14 0 16 7 0 5 0 0 3 0 0

2040 2,068 501 0 823 0 64 15 41 39 368 51 3 65 58 41 0 29 12 0 10 0 0 7 0 0

2050 2,680 649 0 917 0 60 16 65 61 509 81 8 113 118 91 0 42 15 0 16 0 0 10 0 0

0 0 716 585 256 0 256 68 5 13 0 0 118 112 2 0 2 2 0 0 88 47 0 0 588 3 0% 17%

0 3 1,017 794 316 0 385 86 7 13 0 0 210 167 13 10 9 8 3 0 126 63 0 0 837 24 2% 21%

0 8 1,245 928 356 0 484 79 9 19 0 0 298 212 22 22 18 16 8 0 155 69 0 0 1,030 44 4% 24%

0 16 1,473 1,063 396 0 584 71 11 25 0 0 386 258 30 34 27 23 14 0 184 74 0 0 1,223 64 4% 26%

0 29 2,097 1,426 513 0 833 64 15 41 0 0 629 368 51 65 45 58 41 0 263 87 0 0 1,752 117 6% 30%

0 42 2,722 1,674 664 0 933 61 16 65 0 0 984 509 81 113 72 118 91 0 345 91 0 0 2,293 194 7% 36%

table 13.5.2 africa: final energy consumption in transport pj/a 2012 2020 road 3,657 4,405 fossil fuels 3,640 4,387 biofuels 0 0 synfuels 0 0 natural gas 17 16 hydrogen 0 0 electricity 0 3 rail 32 34 fossil fuels 12 13 biofuels 0 0 synfuels 0 0 electricity 20 21 navigation 26 30 fossil fuels 26 30 biofuels 0 0 synfuels 0 0 aviation 105 139 fossil fuels 105 139 biofuels 0 0 synfuels 0 0 total (incl. pipelines) 3,857 4,650 fossil fuels 3,783 4,568 biofuels (incl. biogas) 0 0 synfuels 0 0 natural gas 54 58 hydrogen 0 0 electricity 20 24 total res 3 5 res share 0% 0%

2025 5,110 5,086 0 0 18 0 6 35 14 0 0 22 30 30 0 0 140 140 0 0 5,361 5,270 0 0 63 0 28 7 0%

2030 5,786 5,758 0 0 20 0 9 37 14 0 0 22 31 31 0 0 170 170 0 0 6,071 5,972 0 0 68 0 32 8 0%

2040 7,839 7,795 0 0 26 0 17 39 15 0 0 24 31 31 0 0 275 275 0 0 8,238 8,117 0 0 81 0 41 12 0%

2050 9,881 9,820 0 0 35 0 26 42 17 0 0 25 32 32 0 0 389 389 0 0 10,405 10,258 0 0 95 0 51 19 0%

2040 0 0 0 0 0 114 87 27 0 0 14,366 6,380 7,322 104 0 0 560 0 14,480 6,467 7,349 104 0 0 560 0 53%

2050 0 0 0 0 0 243 169 74 0 0 16,825 7,892 8,106 186 0 0 641 0 17,068 8,061 8,180 186 0 0 641 0 50%

table 13.5.3 africa: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 0 0 0 0 0 7,354 2,710 4,334 5 0 0 305 0 7,354 2,710 4,334 5 0 0 305 0 60%

2020 0 0 0 0 0 8 6 1 0 0 9,295 3,614 5,273 17 0 0 390 0 9,302 3,621 5,274 17 0 0 390 0 58%

2025 0 0 0 0 0 22 18 4 0 0 10,439 4,193 5,792 33 0 0 420 0 10,461 4,211 5,796 33 0 0 420 0 57%

2030 0 0 0 0 0 49 39 10 0 0 11,635 4,782 6,344 50 0 0 460 0 11,685 4,822 6,354 50 0 0 460 0 56%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

332

2012 157 129 42 0 59 26 2 2 0 26 25 1 0 0 0 0 0 0 1 1% 17%

table 13.5.5: africa: final energy demand pj/a 2012 total (incl. non-energy use) 22,565 total energy use1 21,718 transport 3,857 oil products 3,783 natural gas 54 biofuels 0 synfuels 0 electricity 20 RES electricity 3 hydrogen 0 res share transport 0% industry 3,447 electricity 872 RES electricity 144 public district heat 0 RES district heat 0 hard coal & lignite 350 oil products 650 gas 738 solar 0 biomass 837 geothermal 0 hydrogen 0 res share industry 28% other sectors 14,413 electricity 1,223 RES electricity 202 public district heat 0 RES district heat 0 hard coal & lignite 295 oil products 1,107 gas 305 solar 5 biomass 11,479 geothermal 0 hydrogen 0 res share other sectors 81% total res 12,671 res share 58% non energy use 847 oil 427 gas 363 coal 57

2020 249 193 58 0 100 33 3 2 0 54 38 5 0 6 2 1 1 0 12 5% 22%

2020 27,547 26,559 4,650 4,568 58 0 0 24 5 0 0% 4,561 1,180 244 0 0 623 779 872 4 1,104 0 0 30% 17,349 1,809 374 0 0 296 1,566 354 14 13,310 0 0 79% 15,054 57% 988 484 441 63

2025 308 226 68 0 123 32 4 3 0 80 49 8 0 14 4 2 3 0 22 7% 26%

2025 30,556 29,483 5,361 5,270 63 0 0 28 7 0 0% 5,314 1,398 335 0 0 713 848 996 8 1,351 0 0 32% 18,808 2,283 546 0 0 302 1,858 417 26 13,923 0 0 77% 16,195 55% 1,073 517 488 68

2030 367 258 77 0 145 30 5 4 0 105 60 12 0 21 6 4 4 0 32 9% 29%

2030 33,564 32,409 6,071 5,972 68 0 0 32 8 0 0% 6,068 1,616 423 0 0 804 917 1,120 12 1,599 0 0 34% 20,269 2,756 722 0 0 309 2,151 480 38 14,536 0 0 75% 17,337 53% 1,156 546 536 74

2040 522 341 101 0 205 29 7 6 0 175 86 19 1 40 9 9 11 0 59 11% 33%

2050 674 395 131 0 229 27 7 9 0 271 119 30 2 69 14 18 20 0 99 15% 40%

2040 40,579 39,263 8,238 8,117 81 0 0 41 12 0 0% 8,262 2,247 674 0 0 1,072 1,064 1,441 29 2,409 0 0 38% 22,763 4,020 1,206 0 0 335 2,950 655 75 14,728 0 0 70% 19,134 49% 1,315 596 635 84

2050 47,275 45,727 10,405 10,258 95 0 0 51 19 0 0% 10,116 3,015 1,089 0 0 1,236 1,095 1,632 54 3,085 0 0 42% 25,207 5,188 1,875 0 0 363 3,966 874 132 14,683 0 0 66% 20,937 46% 1,548 672 778 99

1 excluding heat produced by chp autoproducers

table 13.5.6: africa: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (545 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 415 238 0 117 51 8 0 0 0 0 0 415 238 0 117 60

2020 531 295 0 168 62 7 2 2 0 1 0 533 296 0 168 69

2025 588 325 0 199 55 9 6 4 0 1 0 593 329 0 200 64

2030 646 354 0 232 48 11 11 8 0 3 0 657 363 0 235 60

2040 822 446 0 319 42 15 20 15 0 5 0 842 461 0 324 57

2050 1,039 620 0 363 40 16 27 19 0 7 0 1,065 639 0 370 56

710 580 1,052 193% 123 128 285 415 102 1,084 1.0

672 524 1,311 240% 167 165 343 531 104 1,312 1.0

639 477 1,468 269% 191 191 396 588 102 1,468 1.0

619 446 1,626 298% 217 217 449 646 97 1,634 1.0

590 402 2,106 386% 280 289 610 822 105 1,999 1.0

636 391 2,617 480% 315 380 771 1,039 111 2,393 1.1

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.5.7: africa: primary energy demand pj/a 2012 total 30,968 fossil 15,610 hard coal (& non-renewable waste) 4,407 lignite 0 natural gas 4,182 crude oil 7,020 nuclear 143 renewables 15,216 hydro 404 wind 8 solar 6 biomass (& renewable waste) 14,739 geothermal 58 ocean energy 0 of which non-energy use 847 net electricity imports (final energy) 24 total res incl. net electricity import 15,220 res share 49%

2020 38,118 19,194 5,057 0 5,432 8,704 143 18,781 600 48 66 17,848 219 0 988 33 18,788 49%

2025 42,477 21,755 5,683 0 6,285 9,787 207 20,514 764 78 144 19,149 379 0 1,073 31 20,522 48%

2030 46,910 24,447 6,308 0 7,269 10,870 272 22,191 928 108 222 20,407 526 0 1,156 30 22,199 47%

2040 57,778 31,798 7,892 0 9,771 14,135 453 25,527 1,325 184 489 22,367 1,162 0 1,315 21 25,533 44%

2050 67,023 36,966 9,165 0 10,264 17,537 706 29,351 1,832 291 921 24,180 2,126 0 1,548 21 29,358 44%

energy

a f r i ca : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.5.10: africa: installed capacity gw

table 13.5.8 africa: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 Renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share (domestic generation)

2012 716 256 0 256 0 68 5 13 2 112 2 0 0 2 0 0 0 0 0 0 0 0 0 0 0

2020 971 251 0 356 0 54 6 8 13 150 58 1 44 8 23 0 10 0 0 4 0 0 6 0 0

2025 1,132 216 0 354 0 39 6 4 14 162 139 18 126 25 42 5 68 0 0 31 0 0 35 1 0

2030 1,450 159 0 301 0 20 5 0 16 175 284 85 290 61 122 18 98 0 0 49 0 0 44 4 0

2040 2,503 11 0 206 0 6 4 0 16 200 631 222 690 125 564 50 145 0 0 74 4 0 52 12 7

2050 4,096 0 0 130 0 0 3 0 18 225 961 350 1,089 208 1,362 100 170 0 0 78 27 0 56 17 19

0 0 716 585 256 0 256 68 5 13 0 0 118 112 2 0 2 2 0 0 88 47 0 0 588 3 0% 17%

0 10 981 671 251 0 360 54 6 8 0 0 302 150 58 44 19 8 23 0 126 63 0 0 791 102 10% 31%

0 68 1,199 646 216 0 385 39 6 4 0 0 549 162 139 126 49 26 42 5 145 67 1 0 966 270 23% 46%

0 98 1,548 534 159 0 350 20 5 0 0 0 1,014 175 284 290 60 65 122 18 177 67 18 0 1,179 592 38% 65%

0 145 2,648 297 11 0 276 6 4 0 11 10 2,340 200 631 690 68 137 564 50 279 61 209 0 1,859 1,371 52% 89%

0 170 4,266 183 0 0 180 0 3 0 46 44 4,037 225 961 1,089 74 225 1,362 100 434 45 577 0 2,889 2,150 50% 96%

table 13.5.9 africa: final energy consumption in transport pj/a 2012 2020 road 3,657 4,131 fossil fuels 3,640 4,109 biofuels 0 0 synfuels 0 0 natural gas 17 21 hydrogen 0 0 electricity 0 2 rail 32 45 fossil fuels 12 19 biofuels 0 0 synfuels 0 0 electricity 20 26 navigation 26 45 fossil fuels 26 44 biofuels 0 1 synfuels 0 0 aviation 105 125 fossil fuels 105 125 biofuels 0 0 synfuels 0 0 total (incl. pipelines) 3,857 4,386 fossil fuels 3,783 4,296 biofuels (incl. biogas) 0 2 synfuels 0 0 natural gas 54 61 hydrogen 0 0 electricity 20 28 total res 3 10 res share 0% 0%

2025 4,407 4,183 129 0 40 1 53 49 19 1 0 29 58 55 3 0 139 139 0 0 4,694 4,396 133 0 80 1 83 172 4%

2030 4,663 4,221 222 0 46 47 127 56 18 2 0 36 62 55 7 0 150 148 1 0 4,974 4,442 234 0 87 47 164 372 7%

2040 4,991 3,560 352 0 72 437 570 64 14 4 0 46 81 67 15 0 194 178 16 0 5,374 3,819 386 0 108 437 625 1,328 25%

2050 5,436 2,457 434 0 163 990 1,392 94 8 4 0 82 89 62 27 0 244 171 73 0 5,907 2,698 537 0 183 990 1,498 2,917 49%

table 13.5.10 africa: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

[r]evolution

2012 0 0 0 0 0 0 0 0 0 0 7,354 2,710 4,334 5 0 0 305 0 7,354 2,710 4,334 5 0 0 305 0 60%

2020 0 0 0 0 0 25 12 13 0 0 8,593 3,330 4,759 43 25 5 431 0 8,619 3,342 4,772 43 25 5 431 0 58%

2025 0 0 0 0 0 194 95 87 12 0 9,151 3,187 5,098 203 56 26 581 0 9,346 3,282 5,185 203 69 26 581 0 62%

2030 0 0 0 0 0 319 156 127 35 0 9,703 2,809 5,219 701 90 88 796 0 10,022 2,965 5,346 701 125 88 796 0 68%

2040 0 0 0 0 0 610 235 215 104 56 11,149 1,996 5,450 1,820 141 313 1,430 0 11,759 2,231 5,664 1,820 245 313 1,430 56 80%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2050 0 0 0 0 0 951 183 404 153 211 12,566 955 4,809 3,336 201 589 2,507 168 13,517 1,138 5,213 3,336 354 589 2,507 379 91%

2012 157 129 42 0 59 26 2 2 0 26 25 1 0 0 0 0 0 0 1 1% 17%

table 13.5.12: africa: final energy demand pj/a 2012 total (incl. non-energy use) 22,565 total energy use1 21,718 transport 3,857 oil products 3,783 natural gas 54 biofuels 0 synfuels 0 electricity 20 RES electricity 3 hydrogen 0 res share transport 0% industry 3,447 electricity 872 RES electricity 144 public district heat 0 RES district heat 0 hard coal & lignite 350 oil products 650 gas 738 solar 0 biomass 837 geothermal 0 hydrogen 0 res share industry 28% other sectors 14,413 electricity 1,223 RES electricity 202 public district heat 0 RES district heat 0 hard coal & lignite 295 oil products 1,107 gas 305 solar 5 biomass 11,479 geothermal 0 hydrogen 0 res share other sectors 81% total res 12,671 res share 58% non energy use 847 oil 427 gas 363 coal 57

2020 254 157 46 0 88 21 2 1 0 96 34 23 0 28 4 1 7 0 50 20% 38%

2020 24,826 23,868 4,386 4,296 61 2 0 28 9 0 0% 4,049 1,100 339 0 0 469 697 831 12 911 28 0 32% 15,432 1,721 530 0 0 332 1,362 427 31 11,559 0 0 79% 13,420 56% 958 478 419 61

2025 353 158 43 0 96 16 2 1 0 195 37 52 5 77 10 4 11 3 132 37% 55%

2025 25,201 24,182 4,694 4,396 80 133 0 83 38 1 4% 4,071 1,216 557 0 0 370 594 839 49 938 65 0 40% 15,416 2,177 996 0 0 380 1,218 498 154 10,980 9 0 79% 13,921 58% 1,019 509 425 85

2030 543 162 40 0 109 10 2 0 0 381 41 102 25 177 13 10 30 9 288 53% 70%

2030 25,312 24,237 4,974 4,442 87 234 0 164 108 47 7% 4,163 1,383 906 0 0 229 475 809 175 975 117 0 52% 15,100 2,695 1,765 0 0 282 989 612 526 9,961 36 0 81% 14,832 61% 1,075 536 427 111

2040 997 131 5 0 120 4 2 0 3 863 47 220 65 423 15 20 113 25 668 67% 87%

2040 26,637 25,479 5,374 3,819 108 386 0 625 554 437 25% 4,739 1,899 1,685 0 0 161 114 766 461 1,083 254 0 74% 15,366 4,168 3,698 0 0 189 417 691 1,359 8,427 116 0 89% 18,411 72% 1,157 578 413 166

2050 1,539 133 0 0 130 0 3 0 12 1,394 53 333 102 669 17 34 239 50 1,052 68% 91%

2050 28,535 27,297 5,907 2,698 183 537 0 1,498 1,432 990 49% 5,591 2,569 2,457 0 0 15 25 437 703 1,296 369 177 89% 15,799 6,334 6,058 0 0 55 14 570 2,633 5,918 274 0 94% 22,795 84% 1,238 618 393 228

1 excluding heat produced by chp autoproducers

table 13.5.13: africa: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (545 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 415 238 0 117 51 8 0 0 0 0 0 415 238 0 117 60

2020 435 235 0 156 39 6 2 0 0 2 0 438 235 0 158 45

2025 379 200 0 146 27 6 17 0 0 17 0 396 200 0 163 33

2030 284 145 0 121 13 5 27 0 0 26 0 311 145 0 147 19

2040 104 10 0 87 4 4 35 0 0 35 0 139 10 0 122 8

2050 53 0 0 50 0 3 24 0 0 24 0 77 0 0 74 3

710 580 1,052 193% 123 128 285 415 102 1,084 1.0

652 446 1,138 209% 145 157 323 435 77 1,312 0.9

612 330 1,071 196% 143 155 332 379 63 1,468 0.7

581 201 929 171% 129 135 336 284 46 1,634 0.6

468 53 606 111% 101 88 290 104 22 1,999 0.3

420 18 363 67% 52 38 212 53 8 2,393 0.2

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.5.14: africa: primary energy demand pj/a 2012 total 30,968 fossil 15,610 hard coal (& non-renewable waste) 4,407 lignite 0 natural gas 4,182 crude oil 7,020 nuclear 143 renewables 15,216 hydro 404 wind 8 solar 6 biomass (& renewable waste) 14,739 geothermal 58 ocean energy 0 of which non-energy use 847 net electricity imports (final energy) 24 total res incl. net electricity import 15,220 res share 49%

2020 34,500 17,285 4,282 0 5,229 7,774 87 17,127 540 209 285 15,847 247 0 958 0 17,127 50%

2025 34,942 16,901 4,040 0 5,369 7,491 44 17,998 583 501 807 15,387 702 18 1,019 -76 17,983 52%

2030 34,829 15,235 3,068 0 5,170 6,997 0 19,595 630 1,024 2,182 14,104 1,590 65 1,075 -386 19,294 56%

2040 35,521 11,033 1,004 0 4,773 5,256 0 24,488 720 2,272 6,335 11,927 3,054 180 1,157 -864 23,593 68%

2050 37,499 6,891 298 0 3,059 3,534 0 30,607 810 3,460 12,162 9,183 4,632 360 1,238 -1,152 29,399 81%

a f r i ca : a d va n c e d e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.5.18: africa: installed capacity gw

table 13.5.15 africa: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share (domestic generation)

2012 716 256 0 256 0 68 5 13 2 112 2 0 0 2 0 0 0 0 0 0 0 0 0 0 0

2020 978 237 0 356 0 54 6 8 18 150 68 6 50 8 23 0 10 0 0 4 0 0 6 0 0

2025 1,160 154 0 354 0 39 6 4 24 162 179 28 156 25 52 5 68 0 0 31 0 0 35 1 0

2030 1,633 82 0 301 0 20 5 0 26 175 344 95 410 61 192 18 98 0 0 49 0 0 44 4 0

2040 3,552 1 0 185 46 6 4 0 27 200 945 292 977 124 994 90 145 0 0 65 16 0 59 13 7

2050 6,016 0 0 126 126 0 0 0 30 225 1,535 450 1,379 201 2,340 180 170 0 0 54 54 0 73 24 19

0 0 716 585 256 0 256 68 5 13 0 0 118 112 2 0 2 2 0 0 88 47 0 0 588 3 0% 17%

0 10 988 657 237 0 360 54 6 8 0 0 323 150 68 50 24 8 23 0 126 63 0 0 798 118 12% 33%

0 68 1,227 584 154 0 385 39 6 4 0 0 639 162 179 156 59 26 52 5 145 67 1 0 994 340 28% 52%

0 98 1,731 457 82 0 350 20 5 0 0 0 1,274 175 344 410 70 65 192 18 177 67 71 0 1,292 772 45% 74%

0 145 3,697 198 1 0 188 6 4 0 70 65 3,429 200 945 977 86 137 994 90 279 61 687 288 2,061 2,012 54% 95%

0 170 6,186 0 0 0 0 0 0 0 199 199 5,987 225 1,535 1,379 103 225 2,340 180 434 45 1,338 735 3,137 3,094 50% 100%

table 13.5.16 africa: final energy consumption in transport pj/a 2012 2020 2025 road 3,657 4,072 4,208 fossil fuels 3,640 4,039 3,938 biofuels 0 0 122 synfuels 0 0 0 natural gas 17 19 33 hydrogen 0 0 1 electricity 0 14 114 rail 32 56 85 fossil fuels 12 17 16 biofuels 0 0 1 synfuels 0 0 0 electricity 20 38 68 navigation 26 45 58 fossil fuels 26 45 58 biofuels 0 0 1 synfuels 0 0 0 aviation 105 125 139 fossil fuels 105 124 137 biofuels 0 1 1 synfuels 0 0 0 total (incl. pipelines) 3,857 4,339 4,532 fossil fuels 3,783 4,225 4,148 biofuels (incl. biogas) 0 1 125 synfuels 0 0 0 natural gas 54 60 73 hydrogen 0 0 1 electricity 20 52 184 total res 3 19 222 res share 0% 0% 5%

2030 4,324 3,689 194 0 29 182 229 113 13 2 0 98 62 57 6 0 148 135 13 0 4,690 3,893 216 0 68 182 331 594 13%

2040 3,953 1,916 338 370 16 926 757 162 6 2 2 151 81 53 14 15 190 123 32 35 4,801 2,099 386 422 41 926 929 2,537 53%

2050 3,521 0 524 979 0 1,542 1,455 283 0 2 4 277 89 0 31 58 229 0 80 149 5,148 0 637 1,191 0 1,542 1,778 5,148 100%

table 13.5.17 africa: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 0 0 0 0 0 7,354 2,710 4,334 5 0 0 305 0 7,354 2,710 4,334 5 0 0 305 0 60%

2020 0 0 0 0 0 25 12 13 0 0 8,593 3,330 4,759 43 25 5 431 0 8,619 3,342 4,772 43 25 5 431 0 58%

2025 0 0 0 0 0 194 95 87 12 0 9,151 3,187 5,098 203 56 26 581 0 9,346 3,282 5,185 203 69 26 581 0 62%

2030 0 0 0 0 0 319 156 127 35 0 9,703 2,665 5,219 701 90 88 940 0 10,022 2,821 5,346 701 125 88 940 0 69%

2040 0 0 0 0 0 624 164 245 117 98 11,135 1,536 5,446 1,818 140 312 1,595 289 11,759 1,700 5,690 1,818 257 312 1,595 387 85%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

334

2050 0 0 0 0 0 1,049 0 526 214 308 12,468 0 5,014 3,315 195 582 2,756 606 13,517 0 5,540 3,315 409 582 2,756 914 100%

2012 157 129 42 0 59 26 2 2 0 26 25 1 0 0 0 0 0 0 1 1% 17%

table 13.5.19: africa: final energy demand pj/a 2012 total (incl. non-energy use) 22,565 total energy use1 21,718 transport 3,857 oil products 3,783 natural gas 54 biofuels 0 synfuels 0 electricity 20 RES electricity 3 hydrogen 0 res share transport 0% industry 3,447 electricity 872 RES electricity 144 public district heat 0 RES district heat 0 hard coal & lignite 350 oil products 650 gas 738 solar 0 biomass 837 geothermal 0 hydrogen 0 res share industry 28% other sectors 14,413 electricity 1,223 RES electricity 202 public district heat 0 RES district heat 0 hard coal & lignite 295 oil products 1,107 gas 305 solar 5 biomass 11,479 geothermal 0 hydrogen 0 res share other sectors 81% total res 12,671 res share 58% non energy use 847 oil 427 gas 363 coal 57

2020 260 154 43 0 88 21 2 1 0 104 34 26 2 31 5 1 7 0 58 22% 40%

2020 24,778 23,820 4,339 4,225 60 1 0 52 17 0 0% 4,049 1,100 360 0 0 469 697 831 12 911 28 0 32% 15,432 1,721 563 0 0 332 1,362 427 31 11,559 0 0 79% 13,482 57% 958 478 419 61

2025 378 145 31 0 96 16 2 1 0 232 37 67 8 96 12 4 14 3 165 44% 61%

2025 25,039 24,020 4,532 4,148 73 125 0 184 96 1 5% 4,071 1,216 633 0 0 370 594 839 49 938 65 0 41% 15,416 2,177 1,133 0 0 380 1,218 498 154 10,980 9 0 80% 14,184 59% 1,019 509 425 85

2030 639 142 20 0 109 10 2 0 0 497 41 124 28 250 15 10 48 9 383 60% 78%

2030 25,080 24,005 4,690 3,893 68 216 0 331 244 182 13% 4,183 1,411 1,038 0 0 229 471 806 175 975 117 0 55% 15,131 2,909 2,141 0 0 197 977 525 526 9,961 36 0 84% 15,563 65% 1,075 536 427 111

2040 1,420 117 0 0 111 4 2 0 39 1,264 47 333 85 598 21 20 199 45 977 69% 89%

2040 26,223 25,065 4,801 2,099 41 386 422 929 878 926 53% 4,775 1,970 1,861 0 0 160 106 565 459 1,078 253 186 80% 15,489 4,523 4,274 0 0 149 396 394 1,359 8,427 116 124 92% 20,657 82% 1,157 578 413 166

2050 2,180 0 0 0 0 0 0 0 175 2,004 53 541 131 847 30 34 411 90 1,478 68% 92%

2050 28,022 26,784 5,148 0 0 637 1,191 1,778 1,778 1,542 100% 5,555 2,740 2,740 0 0 0 0 0 682 1,256 358 519 100% 16,081 6,776 6,776 0 0 0 0 0 2,633 6,279 274 119 100% 26,784 100% 1,238 618 393 228

1 excluding heat produced by chp autoproducers

table 13.5.20 africa: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (545 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 415 238 0 117 51 8 0 0 0 0 0 415 238 0 117 60

2020 422 222 0 156 39 6 2 0 0 2 0 424 222 0 158 45

2025 321 142 0 146 27 6 17 0 0 17 0 339 142 0 163 33

2030 214 75 0 121 13 5 27 0 0 26 0 240 75 0 147 19

2040 67 1 0 58 4 4 24 0 0 24 0 91 1 0 83 8

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

710 580 1,052 193% 123 128 285 415 102 1,084 1.0

646 430 1,117 205% 145 157 318 422 75 1,312 0.9

580 276 991 182% 143 155 313 321 59 1,468 0.7

525 139 793 145% 128 121 294 214 36 1,634 0.5

460 25 379 69% 79 66 158 67 9 1,999 0.2

0 0 0 0% 0 0 0 0 0 2,393 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.5.21: africa: primary energy demand pj/a 2012 total 30,968 fossil 15,610 hard coal (& non-renewable waste) 4,407 lignite 0 natural gas 4,182 crude oil 7,020 nuclear 143 renewables 15,216 hydro 404 wind 8 solar 6 biomass (& renewable waste) 14,739 geothermal 58 ocean energy 0 of which non-energy use 847 net electricity imports (final energy) 24 total res incl. net electricity import 15,220 res share 49%

2020 34,260 16,920 3,961 0 5,259 7,700 87 17,253 540 245 306 15,915 247 0 958 0 17,253 50%

2025 34,155 15,711 3,055 0 5,425 7,231 44 18,401 583 645 951 15,502 702 18 1,019 -76 18,386 54%

2030 33,825 13,231 1,693 0 5,134 6,404 0 20,594 630 1,240 2,866 14,203 1,590 65 1,075 -444 20,197 61%

2040 35,853 7,319 540 0 3,360 3,419 0 28,534 720 3,402 8,914 12,128 3,046 324 1,157 -1,152 27,448 79%

2050 39,517 1,259 228 0 414 618 0 38,258 810 5,527 16,705 9,971 4,596 648 1,238 -1,786 36,472 97%

energy

a f r i ca : i n v e st m e n t a n d e m p loy m e n t table 13.5.22: africa: investments in electricity generation unit 201220212031ref 2020 2030 2040 fossil (w/o chp) billion $ 91.9 90.7 142.3 nuclear billion $ 1.8 8.3 10.4 chp (fossil + renewable) billion $ 2.1 7.9 7.7 renewables (w/o chp) billion $ 78.0 129.6 189.2 total billion $ 173.8 236.5 349.7 conventional (fossil & nuclear) billion $ 95.5 105.5 158.8 renewables billion $ 78.3 131.0 190.9 biomass billion $ 3.9 7.7 11.1 hydro billion $ 39.5 62.2 73.1 wind billion $ 6.3 10.6 17.1 pv billion $ 11.9 19.3 26.1 geothermal billion $ 11.7 18.4 32.5 solar thermal power plants billion $ 5.1 12.8 30.9 ocean energy billion $ 0.0 0.0 0.0 e[r] fossil (w/o chp) billion $ 61.1 25.3 49.8 nuclear billion $ 1.0 0.0 0.0 chp (fossil + renewable) billion $ 8.5 66.3 24.7 renewables (w/o chp) billion $ 157.5 585.9 1,011.6 total billion $ 228.0 677.5 1,086.1 conventional (fossil & nuclear) billion $ 67.5 72.9 67.4 renewables billion $ 160.6 604.6 1,018.7 biomass billion $ 8.7 19.8 12.9 hydro billion $ 30.3 24.4 23.3 wind billion $ 32.7 161.9 258.0 pv billion $ 48.1 194.5 279.5 geothermal billion $ 11.6 60.6 58.6 solar thermal power plants billion $ 29.2 98.9 330.3 ocean energy billion $ 0.0 44.6 56.1 adv e[r] fossil (w/o chp) billion $ 57.0 16.2 70.9 nuclear billion $ 1.0 0.0 0.0 chp (fossil + renewable) billion $ 8.5 66.3 23.0 renewables (w/o chp) billion $ 175.1 779.1 1,624.7 total billion $ 241.5 861.6 1,718.5 conventional (fossil & nuclear) billion $ 63.3 63.8 83.3 renewables billion $ 178.2 797.8 1,635.2 biomass billion $ 11.0 22.1 23.1 hydro billion $ 30.3 24.4 23.3 wind billion $ 41.7 191.5 420.1 pv billion $ 54.5 283.4 387.5 geothermal billion $ 11.6 60.6 57.6 solar thermal power plants billion $ 29.2 171.1 602.9 ocean energy billion $ 0.0 44.6 120.7

20412050 142.5 14.9 10.1 262.0 429.5 164.7 264.7 17.4 91.7 26.3 34.2 52.5 42.7 0.0

2012unit 2050 467.3 billion $/a 35.4 billion $/a 27.9 billion $/a 658.9 billion $/a 1,189.4 billion $/a 524.5 billion $/a 664.9 billion $/a 40.1 billion $/a 266.4 billion $/a 60.3 billion $/a 91.5 billion $/a 115.0 billion $/a 91.5 billion $/a 0.0 billion $/a

annual average

34.0 0.0 39.0 1,349.9 1,422.9 53.8 1,369.0 22.9 23.2 339.9 308.3 76.4 533.2 65.0

170.2 billion $/a 1.0 billion $/a 138.5 billion $/a 3,104.9 billion $/a 3,414.5 billion $/a 261.7 billion $/a 3,152.9 billion $/a 64.3 billion $/a 101.2 billion $/a 792.5 billion $/a 830.4 billion $/a 207.3 billion $/a 991.5 billion $/a 165.7 billion $/a

4.4 0.0 3.6 79.6 87.6 6.7 80.8 1.6 2.6 20.3 21.3 5.3 25.4 4.2

64.4 0.0 38.0 1,968.7 2,071.1 78.5 1,992.6 37.2 23.2 505.6 363.8 73.2 876.8 112.8

208.4 billion $/a 1.0 billion $/a 135.8 billion $/a 4,547.6 billion $/a 4,892.8 billion $/a 288.9 billion $/a 4,603.8 billion $/a 93.4 billion $/a 101.2 billion $/a 1,158.9 billion $/a 1,089.2 billion $/a 203.1 billion $/a 1,680.0 billion $/a 278.0 billion $/a

5.3 0.0 3.5 116.6 125.5 7.4 118.0 2.4 2.6 29.7 27.9 5.2 43.1 7.1

2012-2050 12.0 0.9 0.7 16.9 30.5 13.4 17.0 1.0 6.8 1.5 2.3 2.9 2.3 0.0

[r]evolution

table 13.5.23: africa: investments in renewable heat generation unit 201220212031ref 2020 2030 2040 heat pumps billion $ 0.0 0.0 0.0 deep geothermal billion $ 0.0 0.0 0.0 solar thermal billion $ 1.0 2.0 4.4 biomass billion $ 302.6 281.0 58.5 total billion $ 303.6 283.0 62.8 e[r] heat pumps billion $ 0.8 21.3 50.9 deep geothermal billion $ 5.5 13.3 13.6 solar thermal billion $ 2.9 38.6 66.6 bomass billion $ 137.7 22.8 13.4 total billion $ 147.0 96.1 144.6 adv e[r] heat pumps billion $ 0.8 21.3 50.8 deep geothermal billion $ 5.5 13.3 13.5 solar thermal billion $ 2.9 38.6 66.3 biomass billion $ 137.7 22.8 13.1 total billion $ 147.0 96.1 143.8

table 13.5.24: africa total employment in the energy sector

20412050 0.0 0.0 6.2 55.7 62.0

2012unit 2050 0.0 billion $/a 0.0 billion $/a 13.6 billion $/a 697.9 billion $/a 711.4 billion $/a

annual average

87.8 20.4 98.7 13.2 220.1

160.9 billion $/a 52.9 billion $/a 206.9 billion $/a 187.1 billion $/a 607.7 billion $/a

4.1 1.4 5.3 4.8 15.6

86.9 19.5 96.3 11.6 214.3

159.9 billion $/a 51.9 billion $/a 204.2 billion $/a 185.2 billion $/a 601.1 billion $/a

4.1 1.3 5.2 4.7 15.4

thousand jobs adv e [ r ] scenariO

reference scenariO

2012-2050 0.0 0.0 0.3 17.9 18.2

2015 366 161 235 6,315 39.6 18.9 7,134

2020 442 179 308 6,930 46.5 18.9 7,925

2025 422 176 384 7,313 53.2 35.2 8,383

2030 455 197 413 7,668 59.8 30 8,823

2020 937 221 453 6,174 25.4 106 7,918

2025 1,825 534 787 5,900 17.9 404 9,468

2030 2,150 832 1,213 5,298 10.5 1,025 10,528

376 223 16 6,521 6,244 158 19 66 6.9 8.1 18.9 0.0 7,134

391 247 23 7,264 6,871 209 28 109 10.1 17.4 18.9 7,925

391 263 27 7,702 7,254 216 36 126 10.7 24.1 35.2 8,383

420 278 29 8,096 7,601 229 42 138 15.1 42.3 30 8,823

111 171 8 7,628 6,228 98 295 751 17 89 43 80 26.4 7,918

79 183 9 9,197 5,994 99 588 1,709 37 294 71 351 53.0 9,468

42 169 8 10,309 5,408 86 1,005 2,058 36 609 82 932 93 10,528

335

m i d d l e e a st : r e f e r e n c e s c e n a r i o table 13.6.1 middle east: electricity generation twh/a 2012 power plants 904 hard coal (& non-renewable waste) 1 lignite 0 gas 552 of which from H2 0 oil 275 diesel 53 nuclear 2 biomass (& renewable waste) 0 hydro 22 wind 0 of which wind offshore 0 pv 0 geothermal 0 solar thermal power plants 0 ocean energy 0 combined heat and power plants 0 hard coal (& non-renewable waste) 0 lignite 0 gas 0 of which from H2 0 oil 0 biomass (& renewable waste) 0 geothermal 0 hydrogen 0 CHP by producer main activity producers 0 autoproducers 0 total generation 904 fossil 880 hard coal (& non-renewable waste) 1 lignite 0 gas 552 oil 275 diesel 53 nuclear 2 hydrogen 0 of which renewable H2 0 renewables (w/o renewable hydrogen) 22 hydro 22 wind 0 pv 0 biomass (& renewable waste) 0 geothermal 0 solar thermal power plants 0 ocean energy 0 distribution losses 116 own consumption electricity 56 electricity for hydrogen production 0 electricity for synfuel production 0 final energy consumption (electricity) 734 fluctuating res (pv, wind, ocean) 0 share of fluctuating res 0% res share (domestic generation) 2%

table 13.6.4: middle east: installed capacity gw 2020 1,204 3 0 809 0 260 72 20 3 28 2 0 4 0 4 0 1 0 0 0 0 0 0 0 0

2025 1,430 5 0 1,013 0 219 94 36 5 33 7 0 10 0 9 0 2 0 0 1 0 1 0 0 0

2030 1,655 6 0 1,216 0 182 113 53 8 37 12 0 15 0 13 0 5 0 0 3 0 2 1 0 0

2040 2,093 7 0 1,585 0 140 133 66 20 43 44 4 31 0 23 0 10 0 0 5 0 3 1 0 0

2050 2,477 9 0 1,842 0 101 153 82 40 50 106 13 57 0 36 0 15 0 0 8 0 5 2 0 0

0 1 1,205 1,143 3 0 809 260 72 20 0 0 41 28 2 4 3 0 4 0 155 75 0 0 977 7 1% 3%

0 2 1,432 1,332 5 0 1,014 220 94 36 0 0 64 33 7 10 6 0 9 0 185 81 0 0 1,168 17 1% 4%

0 5 1,660 1,521 6 0 1,218 183 113 53 0 0 87 37 12 15 8 0 13 0 216 87 0 0 1,360 28 2% 5%

0 10 2,103 1,874 7 0 1,590 144 133 66 0 0 162 43 44 31 21 0 23 0 276 88 0 0 1,741 75 4% 8%

0 15 2,492 2,118 9 0 1,850 106 153 82 0 0 292 50 106 57 42 0 36 0 330 88 0 0 2,078 163 7% 12%

table 13.6.2 middle east: final energy consumption in transport 2012 2020 road 5,226 6,835 fossil fuels 4,981 6,545 biofuels 0 0 synfuels 0 0 natural gas 245 290 hydrogen 0 0 electricity 0 0 rail 2 2 fossil fuels 1 1 biofuels 0 0 synfuels 0 0 electricity 1 1 navigation 0 0 fossil fuels 0 0 biofuels 0 0 synfuels 0 0 aviation 46 62 fossil fuels 46 62 biofuels 0 0 synfuels 0 0 total (incl. pipelines) 6,923 5,293 fossil fuels 5,028 6,608 biofuels (incl. biogas) 0 0 synfuels 0 0 natural gas 263 313 hydrogen 0 0 electricity 1 1 total res 0 0 res share 0% 0%

pj/a 2025 8,197 7,853 0 0 344 0 0 2 1 0 0 1 0 0 0 0 76 76 0 0 8,301 7,930 0 0 369 0 1 0 0%

2030 9,565 9,167 0 0 398 0 0 2 1 0 0 1 0 0 0 0 84 84 0 0 9,679 9,252 0 0 425 0 1 0 0%

2040 11,673 11,166 0 0 507 0 0 2 1 0 0 1 0 0 0 0 116 116 0 0 11,825 11,283 0 0 540 0 1 0 0%

2050 12,486 11,847 0 0 638 0 0 2 1 0 0 1 0 0 0 0 154 154 0 0 12,680 12,002 0 0 676 0 2 0 0%

table 13.6.3 middle east: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 0 0 0 0 0 6,409 5,938 20 7 0 0 445 0 6,409 5,938 20 7 0 0 445 0 1%

2020 0 0 0 0 0 1 1 0 0 0 7,590 6,969 76 25 0 0 520 0 7,591 6,970 76 25 0 0 520 0 2%

2025 0 0 0 0 0 6 5 0 0 0 8,725 7,984 131 40 0 0 570 0 8,731 7,990 131 40 0 0 570 0 2%

2030 0 0 0 0 0 15 13 1 0 0 9,907 9,046 186 55 0 0 620 0 9,922 9,059 188 55 0 0 620 0 3%

2040 0 0 0 0 0 33 28 5 0 0 12,991 11,771 345 94 0 0 780 0 13,024 11,799 350 94 0 0 780 0 4%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

336

2050 0 0 0 0 0 60 44 15 0 0 15,205 13,649 554 149 0 0 852 0 15,265 13,693 569 149 0 0 852 0 5%

2012 256 241 0 0 166 62 12 1 0 15 14 0 0 0 0 0 0 0 0 0% 6%

table 13.6.5: middle east: final energy demand pj/a 2012 total (incl. non-energy use) 18,967 total energy use1 15,306 transport 5,293 oil products 5,028 natural gas 263 biofuels 0 synfuels 0 electricity 1 RES electricity 0 hydrogen 0 res share transport 0% industry 5,271 electricity 578 RES electricity 14 public district heat 0 RES district heat 0 hard coal & lignite 79 oil products 1,453 gas 3,162 solar 0 biomass 0 geothermal 0 hydrogen 0 res share industry 0% other sectors 4,742 electricity 2,064 RES electricity 51 public district heat 0 RES district heat 0 hard coal & lignite 0 oil products 970 gas 1,670 solar 7 biomass 32 geothermal 0 hydrogen 0 res share other sectors 2% total res 104 res share 1% non energy use 3,661 oil 1,734 gas 1,916 coal 10

2020 343 315 1 0 226 69 19 3 0 24 18 1 0 3 0 0 2 0 4 1% 7%

2020 23,152 18,950 6,923 6,608 313 0 0 1 0 0 0% 6,112 734 25 0 0 90 1,551 3,672 1 64 0 0 1% 5,915 2,781 95 0 0 0 995 2,072 24 43 0 0 3% 252 1% 4,202 1,903 2,289 11

2025 387 347 1 0 261 60 25 5 0 34 21 3 0 6 1 0 3 0 9 2% 9%

2025 26,825 22,152 8,301 7,930 369 0 0 1 0 0 0% 7,122 835 37 0 0 87 1,675 4,395 3 128 0 0 2% 6,729 3,370 151 0 0 0 993 2,276 37 52 0 0 4% 408 2% 4,674 2,066 2,596 12

2030 431 379 1 0 296 51 31 8 0 44 23 5 0 9 1 0 5 0 15 3% 10%

2030 30,499 25,366 9,679 9,252 425 0 0 1 0 0 0% 8,132 936 49 0 0 84 1,798 5,118 4 192 0 0 3% 7,554 3,959 207 0 0 0 1,001 2,481 51 62 0 0 4% 564 2% 5,133 2,212 2,909 13

2040 508 424 1 0 344 41 38 9 0 75 26 19 1 19 3 0 8 0 38 7% 15%

2050 593 458 2 0 381 30 44 11 0 124 30 45 4 35 7 0 7 0 80 14% 21%

2040 37,962 31,728 11,825 11,283 540 0 0 1 0 0 0% 10,595 1,175 91 0 0 88 2,012 6,953 7 360 0 0 4% 9,308 5,092 393 0 0 0 1,003 3,040 87 86 0 0 6% 1,024 3% 6,234 2,543 3,675 16

2050 43,112 35,791 12,680 12,002 676 0 0 2 0 0 0% 12,483 1,463 171 0 0 35 2,013 8,404 10 557 0 0 6% 10,628 6,014 705 0 0 0 962 3,401 140 112 0 0 9% 1,695 5% 7,321 2,831 4,490 0

1 excluding heat produced by chp autoproducers

table 13.6.6: middle east: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (554 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 609 1 0 327 210 71 0 0 0 0 0 609 1 0 327 281

2020 798 4 0 449 250 95 0 0 0 0 0 798 4 0 449 345

2025 851 5 0 519 203 124 1 0 0 1 0 853 5 0 520 328

2030 908 6 0 591 161 149 3 0 0 1 1 911 7 0 593 311

2040 1,044 7 0 740 120 177 5 1 0 3 2 1,049 8 0 742 299

2050 1,072 9 0 786 82 195 7 0 0 4 3 1,079 10 0 790 279

691 673 1,670 301% 317 180 422 609 143 218 7.7

698 662 2,064 372% 357 206 553 798 150 253 8.2

640 595 2,305 416% 411 218 663 851 161 272 8.5

599 549 2,551 460% 466 231 773 908 172 289 8.8

560 499 3,050 550% 598 265 945 1,044 198 322 9.5

509 433 3,253 587% 682 284 1,011 1,072 205 349 9.3

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.6.7: middle east: primary energy demand pj/a 2012 2020 total 28,272 34,241 fossil 28,133 33,721 hard coal (& non-renewable waste) 124 174 lignite 1 1 natural gas 14,151 16,906 crude oil 13,856 16,640 nuclear 20 217 renewables 119 303 hydro 80 100 wind 1 9 solar 7 54 biomass (& renewable waste) 32 139 geothermal 0 0 ocean energy 0 0 of which non-energy use 3,661 4,202 net electricity imports (final energy) 7 8 total res incl. net electricity import 120 303 res share 0% 1%

2025 38,572 37,678 188 1 19,331 18,158 396 498 117 27 106 248 0 0 4,674 8 499 1%

2030 43,146 41,876 201 1 21,995 19,679 576 694 135 45 158 357 0 0 5,133 8 694 2%

2040 52,657 50,627 215 1 28,098 22,313 722 1,308 156 158 290 705 0 0 6,234 8 1,309 2%

2050 57,934 54,840 163 1 31,599 23,077 894 2,200 181 383 485 1,151 0 0 7,321 8 2,201 4%

energy

m i d d l e e a st : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.6.8 middle east: electricity generation twh/a 2012 power plants 904 hard coal (& non-renewable waste) 1 lignite 0 gas 552 of which from H2 0 oil 275 diesel 53 nuclear 2 biomass (& renewable waste) 0 hydro 22 wind 0 of which wind offshore 0 pv 0 geothermal 0 solar thermal power plants 0 ocean energy 0 combined heat and power plants 0 hard coal (& non-renewable waste) 0 lignite 0 gas 0 of which from H2 0 oil 0 biomass (& renewable waste) 0 geothermal 0 hydrogen 0 CHP by producer main activity producers 0 autoproducers 0 total generation 904 fossil 880 hard coal (& non-renewable waste) 1 lignite 0 gas 552 oil 275 diesel 53 nuclear 2 hydrogen 0 of which renewable H2 0 renewables (w/o renewable hydrogen) 22 hydro 22 wind 0 pv 0 biomass (& renewable waste) 0 geothermal 0 solar thermal power plants 0 ocean energy 0 distribution losses 116 own consumption electricity 56 electricity for hydrogen production 0 electricity for synfuel production 0 final energy consumption (electricity) 734 fluctuating res (pv, wind, ocean) 0 share of fluctuating res 0% res share (domestic generation) 2%

2020 1,119 0 0 730 0 189 45 3 5 28 35 0 55 1 25 3 15 0 0 3 0 1 7 3 0

2025 1,263 0 0 721 0 132 25 3 8 33 105 10 120 10 95 13 25 0 0 5 0 1 12 6 1

2030 1,596 0 0 699 0 58 15 3 14 37 190 15 250 35 280 14 30 0 0 5 0 1 14 9 1

2040 2,413 0 0 541 0 4 1 0 15 43 302 25 589 77 809 33 55 0 0 7 0 0 23 22 3

2050 3,400 0 0 229 0 2 0 0 18 50 439 40 1,072 66 1,473 51 85 0 0 11 0 0 27 38 9

0 15 1,134 969 0 0 733 190 45 3 0 0 162 28 35 55 12 4 25 3 141 60 1 0 932 93 8% 14%

0 25 1,288 884 0 0 725 134 25 3 1 0 401 33 105 120 20 16 95 13 153 57 5 0 1,068 238 18% 31%

0 30 1,626 778 0 0 704 59 15 3 1 1 843 37 190 250 28 44 280 14 165 54 62 0 1,317 454 28% 52%

0 55 2,468 553 0 0 548 4 1 0 3 2 1,913 43 302 589 38 99 809 33 192 49 344 0 1,823 924 37% 78%

0 85 3,485 242 0 0 240 2 0 0 9 8 3,234 50 439 1,072 45 105 1,473 51 212 44 709 0 2,440 1,562 45% 93%

table 13.6.9 middle east: final energy consumption in transport 2012 2020 road 5,226 6,717 fossil fuels 4,981 6,291 biofuels 0 128 synfuels 0 0 natural gas 245 269 hydrogen 0 0 electricity 0 29 rail 2 3 fossil fuels 1 1 biofuels 0 0 synfuels 0 0 electricity 1 2 navigation 0 0 fossil fuels 0 0 biofuels 0 0 synfuels 0 0 aviation 46 53 fossil fuels 46 53 biofuels 0 0 synfuels 0 0 total (incl. pipelines) 5,293 6,792 fossil fuels 5,028 6,346 biofuels (incl. biogas) 0 128 synfuels 0 0 natural gas 263 288 hydrogen 0 0 electricity 1 30 total res 0 133 res share 0% 2%

pj/a 2025 6,613 5,873 309 0 278 7 146 3 1 0 0 2 0 0 0 0 62 60 1 0 6,696 5,935 310 0 295 7 149 359 5%

2030 6,515 5,091 443 0 326 148 508 4 1 0 0 2 0 0 0 0 65 61 4 0 6,600 5,153 447 0 342 148 511 789 12%

2040 5,787 2,847 502 0 322 874 1,242 3 1 0 0 3 0 0 0 0 80 71 10 0 5,885 2,918 512 0 333 874 1,248 2,158 37%

2050 5,053 524 524 0 331 1,597 2,077 5 0 0 0 5 0 0 0 0 85 51 34 0 5,150 575 558 0 335 1,597 2,085 3,984 77%

table 13.6.10 middle east: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 0 0 0 0 0 6,409 5,938 20 7 0 0 445 0 6,409 5,938 20 7 0 0 445 0 1%

2020 0 0 0 0 0 57 12 17 27 1 7,242 6,138 98 159 110 53 684 0 7,299 6,150 115 159 137 53 684 1 8%

2025 0 0 0 0 0 107 17 31 56 3 7,400 5,879 121 370 144 87 798 0 7,507 5,896 152 370 200 87 798 3 14%

2030 0 0 0 0 0 146 18 41 81 6 7,603 5,391 146 733 180 122 1,031 0 7,749 5,408 187 733 261 122 1,031 6 24%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2040 0 0 0 0 0 333 24 95 198 17 8,024 3,888 207 1,609 231 293 1,796 0 8,357 3,912 302 1,609 429 293 1,796 17 49%

2050 0 0 0 0 0 631 40 196 344 51 8,030 1,633 315 2,020 366 577 2,858 261 8,661 1,673 511 2,020 710 577 2,858 312 78%

[r]evolution

table 13.6.10: middle east: installed capacity gw 2012 total generation 256 fossil 241 hard coal (& non-renewable waste) 0 lignite 0 gas (w/o h2) 166 oil 62 diesel 12 nuclear 1 hydrogen (fuel cells, gas power plants, gas chp) 0 renewables 15 hydro 14 wind 0 of which wind offshore 0 pv 0 biomass (& renewable waste) 0 geothermal 0 solar thermal power plants 0 ocean energy 0 fluctuating res (pv, wind, ocean) 0 share of fluctuating res 0% res share (domestic generation) 6% table 13.6.12: middle east: final energy demand pj/a 2012 total (incl. non-energy use) 18,967 total energy use1 15,306 transport 5,293 oil products 5,028 natural gas 263 biofuels 0 synfuels 0 electricity 1 RES electricity 0 hydrogen 0 res share transport 0% industry 5,271 electricity 578 RES electricity 14 public district heat 0 RES district heat 0 hard coal & lignite 79 oil products 1,453 gas 3,162 solar 0 biomass 0 geothermal 0 hydrogen 0 res share industry 0% other sectors 4,742 electricity 2,064 RES electricity 51 public district heat 0 RES district heat 0 hard coal & lignite 0 oil products 970 gas 1,670 solar 7 biomass 32 geothermal 0 hydrogen 0 res share other sectors 2% total res 104 res share 1% non energy use 3,661 oil 1,734 gas 1,916 coal 10

2020 352 268 0 0 205 51 12 0 0 83 18 16 0 34 2 1 10 2 52 15% 24%

2020 21,530 17,981 6,792 6,346 288 128 0 30 4 0 2% 5,677 772 110 0 0 41 1,133 3,450 88 64 129 0 7% 5,512 2,551 364 0 0 0 903 1,891 71 78 18 0 10% 1,054 6% 3,549 1,574 1,824 151

2025 416 230 0 0 187 36 7 0 0 186 21 45 3 73 3 2 35 6 125 30% 45%

2025 21,950 18,119 6,696 5,935 295 310 0 149 46 7 5% 5,628 846 264 0 0 49 859 3,381 222 92 179 0 13% 5,795 2,851 888 0 0 0 815 1,876 148 80 26 0 20% 2,257 12% 3,831 1,738 1,778 316

2030 572 211 0 0 190 16 4 0 0 360 23 82 5 151 5 6 86 7 240 42% 63%

2030 22,433 18,320 6,600 5,153 342 447 0 511 265 148 12% 5,615 1,010 524 0 0 44 620 3,168 422 120 231 0 23% 6,105 3,221 1,672 0 0 0 613 1,840 311 83 36 0 34% 4,189 23% 4,114 1,907 1,703 504

2040 923 204 0 0 202 1 0 0 1 719 26 130 8 358 7 14 167 17 505 55% 78%

2040 22,228 17,918 5,885 2,918 333 512 0 1,248 968 874 37% 5,634 1,476 1,145 0 0 0 248 2,606 756 176 373 0 43% 6,398 3,840 2,979 0 0 0 413 1,124 853 95 73 0 63% 8,608 48% 4,310 2,084 1,353 873

2050 1,392 222 0 0 220 1 0 0 2 1,168 30 188 13 656 9 15 245 26 870 62% 84%

2050 21,212 17,203 5,150 575 335 558 0 2,085 1,940 1,597 77% 5,607 2,282 2,124 0 0 0 61 1,161 984 272 572 275 75% 6,446 4,417 4,109 0 0 0 119 534 1,036 114 227 0 85% 13,676 80% 4,009 2,019 858 1,133

1 excluding heat produced by chp autoproducers

table 13.6.13: middle east: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (554 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 609 1 0 327 210 71 0 0 0 0 0 609 1 0 327 281

2020 647 0 0 406 182 60 3 0 0 2 1 650 0 0 407 242

2025 525 0 0 369 122 33 3 0 0 3 1 529 0 0 372 156

2030 412 0 0 340 52 20 3 0 0 3 0 415 0 0 343 72

2040 250 0 0 245 3 1 4 0 0 4 0 254 0 0 249 4

2050 98 0 0 96 2 0 6 0 0 6 0 103 0 0 101 2

691 673 1,670 301% 317 180 422 609 143 218 7.7

671 573 1,778 321% 307 187 530 647 105 253 7.0

598 410 1,569 283% 282 179 498 525 85 272 5.8

533 255 1,325 239% 249 161 437 412 66 289 4.6

459 103 818 148% 182 101 256 250 30 322 2.5

426 30 294 53% 81 42 67 98 7 349 0.8

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.6.14: middle east: primary energy demand pj/a 2012 2020 total 28,272 30,971 fossil 28,133 29,509 hard coal (& non-renewable waste) 124 233 lignite 1 0 natural gas 14,151 15,206 crude oil 13,856 14,070 nuclear 20 33 renewables 119 1,430 hydro 80 100 wind 1 126 solar 7 447 biomass (& renewable waste) 32 522 geothermal 0 223 ocean energy 0 11 of which non-energy use 3,661 3,549 net electricity imports (final energy) 7 0 total res incl. net electricity import 120 1,430 res share 0% 5%

2025 30,115 26,914 405 0 14,290 12,219 33 3,168 117 378 1,144 929 554 45 3,831 -19 3,164 11%

2030 29,974 23,973 582 0 13,490 9,901 33 5,969 135 684 2,642 1,239 1,219 50 4,114 -96 5,926 20%

2040 28,943 17,085 893 0 10,115 6,078 0 11,858 156 1,087 6,641 1,473 2,382 119 4,310 -216 11,692 41%

2050 26,297 8,809 1,134 0 4,805 2,870 0 17,488 181 1,581 11,182 1,682 2,680 184 4,009 -288 17,221 66%

m i d d l e e a st : a d va n c e d e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.6.15 middle east: electricity generation twh/a 2012 power plants 904 hard coal (& non-renewable waste) 1 lignite 0 gas 552 of which from H2 0 oil 275 diesel 53 nuclear 2 biomass (& renewable waste) 0 hydro 22 wind 0 of which wind offshore 0 pv 0 geothermal 0 solar thermal power plants 0 ocean energy 0 combined heat and power plants 0 hard coal (& non-renewable waste) 0 lignite 0 gas 0 of which from H2 0 oil 0 biomass (& renewable waste) 0 geothermal 0 hydrogen 0 CHP by producer main activity producers 0 autoproducers 0 total generation 904 fossil 880 hard coal (& non-renewable waste) 1 lignite 0 gas 552 oil 275 diesel 53 nuclear 2 hydrogen 0 of which renewable H2 0 renewables (w/o renewable hydrogen) 22 hydro 22 wind 0 pv 0 biomass (& renewable waste) 0 geothermal 0 solar thermal power plants 0 ocean energy 0 distribution losses 116 own consumption electricity 56 electricity for hydrogen production 0 electricity for synfuel production 0 final energy consumption (electricity) 734 fluctuating res (pv, wind, ocean) 0 share of fluctuating res 0% res share (domestic generation) 2%

2020 1,127 0 0 721 0 189 45 3 5 28 45 0 55 9 25 3 15 0 0 3 0 1 7 3 0

2025 1,318 0 0 677 0 132 25 3 13 36 135 10 155 25 105 13 25 0 0 5 0 1 12 6 1

2030 1,798 0 0 661 0 48 15 3 14 37 248 15 368 35 355 14 30 0 0 5 0 1 14 9 1

2040 3,007 0 0 367 18 2 0 0 15 43 533 45 737 77 1,174 59 55 0 0 7 0 0 23 22 3

2050 4,621 0 0 139 139 0 0 0 18 50 664 65 1,180 116 2,362 92 85 0 0 11 11 0 27 38 9

0 15 1,142 959 0 0 724 190 45 3 0 0 180 28 45 55 12 12 25 3 141 60 1 0 940 103 9% 16%

0 25 1,343 840 0 0 681 134 25 3 1 0 499 36 135 155 25 31 105 13 153 57 22 0 1,105 303 23% 37%

0 30 1,828 730 0 0 666 49 15 3 1 1 1,094 37 248 368 28 44 355 14 165 54 154 0 1,424 630 34% 60%

0 55 3,062 357 0 0 355 2 0 0 21 19 2,683 43 533 737 38 99 1,174 59 192 49 627 107 2,006 1,329 43% 88%

0 85 4,706 0 0 0 0 0 0 0 159 158 4,547 50 664 1,180 45 155 2,362 92 212 44 1,517 59 2,749 1,936 41% 100%

table 13.6.16 middle east: final energy consumption in transport pj/a 2012 2020 2025 road 5,226 6,642 6,356 fossil fuels 4,981 6,212 5,523 biofuels 0 127 291 synfuels 0 0 0 natural gas 245 263 252 hydrogen 0 0 49 electricity 0 41 241 rail 2 20 44 fossil fuels 1 1 1 biofuels 0 0 0 synfuels 0 0 0 electricity 1 19 43 navigation 0 0 0 fossil fuels 0 0 0 biofuels 0 0 0 synfuels 0 0 0 aviation 46 53 62 fossil fuels 46 53 61 biofuels 0 0 0 synfuels 0 0 0 total (incl. pipelines) 5,293 6,735 6,479 fossil fuels 5,028 6,266 5,585 biofuels (incl. biogas) 0 127 291 synfuels 0 0 0 natural gas 263 281 269 hydrogen 0 0 49 electricity 1 61 285 total res 0 136 416 res share 0% 2% 6%

2030 6,031 4,336 377 0 217 382 719 60 1 0 0 59 0 0 0 0 65 59 6 0 6,172 4,396 383 0 230 382 782 1,080 17%

2040 4,976 1,652 461 150 102 1,290 1,472 88 0 0 0 88 0 0 0 0 80 52 21 7 5,309 1,704 482 157 104 1,290 1,572 3,146 59%

2050 4,469 0 417 81 0 1,812 2,240 89 0 0 0 89 0 0 0 0 85 0 71 14 4,731 0 488 95 0 1,812 2,336 4,731 100%

table 13.6.17 middle east: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 0 0 0 0 0 6,409 5,938 20 7 0 0 445 0 6,409 5,938 20 7 0 0 445 0 1%

2020 0 0 0 0 0 57 12 17 27 1 7,242 6,138 98 159 110 53 684 0 7,299 6,150 115 159 137 53 684 1 8%

2025 0 0 0 0 0 107 17 31 56 3 7,400 5,883 121 370 144 87 794 0 7,507 5,901 152 370 200 87 794 3 15%

2030 0 0 0 0 0 146 18 41 81 6 7,603 5,398 146 733 180 122 1,024 0 7,749 5,415 187 733 261 122 1,024 6 25%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

338

2040 0 0 0 0 0 333 23 95 198 18 8,024 3,718 207 1,609 231 293 1,796 170 8,357 3,741 302 1,609 429 293 1,796 188 53%

2050 0 0 0 0 0 631 0 196 344 91 8,030 0 315 2,386 366 577 3,219 1,167 8,661 0 511 2,386 710 577 3,219 1,258 100%

table 13.6.18: middle east: installed capacity gw 2012 total generation 256 fossil 241 hard coal (& non-renewable waste) 0 lignite 0 gas (w/o h2) 166 oil 62 diesel 12 nuclear 1 hydrogen (fuel cells, gas power plants, gas chp) 0 renewables 15 hydro 14 wind 0 of which wind offshore 0 pv 0 biomass (& renewable waste) 0 geothermal 0 solar thermal power plants 0 ocean energy 0 fluctuating res (pv, wind, ocean) 0 share of fluctuating res 0% res share (domestic generation) 6% table 13.6.19: middle east: final energy demand pj/a 2012 total (incl. non-energy use) 18,967 total energy use1 15,306 transport 5,293 oil products 5,028 natural gas 263 biofuels 0 synfuels 0 electricity 1 RES electricity 0 hydrogen 0 res share transport 0% industry 5,271 electricity 578 RES electricity 14 public district heat 0 RES district heat 0 hard coal & lignite 79 oil products 1,453 gas 3,162 solar 0 biomass 0 geothermal 0 hydrogen 0 res share industry 0% other sectors 4,742 electricity 2,064 RES electricity 51 public district heat 0 RES district heat 0 hard coal & lignite 0 oil products 970 gas 1,670 solar 7 biomass 32 geothermal 0 hydrogen 0 res share other sectors 2% total res 104 res share 1% non energy use 3,661 oil 1,734 gas 1,916 coal 10

2020 355 265 0 0 203 51 12 0 0 89 18 21 0 34 2 2 10 2 57 16% 25%

2020 21,472 17,924 6,735 6,266 281 127 0 61 10 0 2% 5,677 772 121 0 0 41 1,133 3,450 88 64 129 0 7% 5,512 2,551 401 0 0 0 903 1,891 71 78 18 0 10% 1,107 6% 3,549 1,574 1,824 151

2025 463 233 0 0 190 36 7 0 0 229 23 59 3 94 4 5 38 6 159 34% 49%

2025 21,734 17,903 6,479 5,585 269 291 0 285 106 49 6% 5,628 846 315 0 0 49 859 3,381 222 92 179 0 14% 5,796 2,846 1,059 0 0 5 815 1,876 148 80 26 0 23% 2,536 14% 3,831 1,738 1,778 316

2030 706 225 0 0 208 14 4 0 0 480 23 107 5 223 5 6 109 7 337 48% 68%

2030 22,095 17,981 6,172 4,396 230 383 0 782 468 382 17% 5,653 1,063 637 0 0 44 611 3,162 422 120 231 0 25% 6,156 3,284 1,967 0 0 8 601 1,833 311 83 36 0 39% 4,886 27% 4,114 1,907 1,703 504

2040 1,203 196 0 0 195 0 0 0 11 996 26 229 15 449 6 14 242 30 707 59% 83%

2040 21,893 17,583 5,309 1,704 104 482 157 1,572 1,387 1,290 59% 5,741 1,624 1,433 0 0 0 231 2,453 756 176 373 128 50% 6,533 4,026 3,553 0 0 0 382 1,049 853 95 73 54 71% 10,619 60% 4,310 2,084 1,353 873

2050 1,587 0 0 0 0 0 0 0 82 1,505 30 285 22 722 8 22 394 46 1,052 66% 95%

2050 21,101 17,092 4,731 0 0 488 95 2,336 2,336 1,812 100% 5,748 2,807 2,807 0 0 0 0 0 1,350 272 572 747 100% 6,613 4,754 4,754 0 0 0 0 0 1,036 114 227 482 100% 17,092 100% 4,009 2,019 858 1,133

1 excluding heat produced by chp autoproducers

table 13.6.20 middle east: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (554 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 609 1 0 327 210 71 0 0 0 0 0 609 1 0 327 281

2020 642 0 0 400 182 60 3 0 0 2 1 645 0 0 402 242

2025 502 0 0 347 122 33 3 0 0 3 1 506 0 0 349 156

2030 384 0 0 321 43 20 3 0 0 3 0 387 0 0 324 63

2040 164 0 0 163 1 0 4 0 0 4 0 168 0 0 166 1

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

691 673 1,670 301% 317 180 422 609 143 218 7.7

672 564 1,765 319% 307 187 523 642 104 253 7.0

602 377 1,514 273% 282 180 468 502 81 272 5.6

531 212 1,217 220% 248 160 369 384 55 289 4.2

470 55 589 106% 171 94 144 164 15 322 1.8

0 0 0 0% 0 0 0 0 0 349 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.6.21: middle east: primary energy demand pj/a 2012 2020 total 28,272 31,038 fossil 28,133 29,317 hard coal (& non-renewable waste) 124 225 lignite 1 0 natural gas 14,151 15,110 crude oil 13,856 13,982 nuclear 20 33 renewables 119 1,688 hydro 80 100 wind 1 162 solar 7 447 biomass (& renewable waste) 32 519 geothermal 0 449 ocean energy 0 11 of which non-energy use 3,661 3,549 net electricity imports (final energy) 7 0 total res incl. net electricity import 120 1,688 res share 0% 5%

2025 29,981 26,103 396 0 13,873 11,835 33 3,845 128 486 1,307 959 919 45 3,831 -19 3,841 13%

2030 29,347 22,536 569 0 13,040 8,927 33 6,778 135 893 3,336 1,145 1,219 50 4,114 -111 6,715 23%

2040 28,334 13,712 877 0 8,185 4,650 0 14,622 156 1,918 8,488 1,465 2,382 214 4,310 -288 14,364 51%

2050 27,302 4,054 1,133 0 903 2,019 0 23,247 181 2,391 15,137 1,628 3,580 330 4,009 -446 22,801 85%

energy

m i d d l e e a st : i n v e st m e n t a n d e m p loy m e n t table 13.6.22: middle east: investments in electricity generation unit 201220212031ref 2020 2030 2040 fossil (w/o chp) billion $ 99.3 94.2 155.5 nuclear billion $ 10.4 17.7 7.2 chp (fossil + renewable) billion $ 0.5 3.3 2.8 renewables (w/o chp) billion $ 40.0 58.5 80.2 total billion $ 150.2 173.7 245.7 conventional (fossil & nuclear) billion $ 110.2 114.9 165.2 renewables billion $ 40.1 58.7 80.5 biomass billion $ 0.9 2.0 5.0 hydro billion $ 21.8 22.6 17.7 wind billion $ 1.6 6.5 22.8 pv billion $ 4.8 8.7 12.8 geothermal billion $ 0.0 0.0 0.0 solar thermal power plants billion $ 10.9 19.0 22.1 ocean energy billion $ 0.0 0.0 0.0 e[r] fossil (w/o chp) billion $ 67.5 21.7 99.6 nuclear billion $ 5.1 0.0 0.0 chp (fossil + renewable) billion $ 8.9 5.6 12.3 renewables (w/o chp) billion $ 183.9 815.1 919.9 total billion $ 265.4 842.4 1,031.8 conventional (fossil & nuclear) billion $ 77.6 23.6 102.8 renewables billion $ 187.8 818.8 929.1 biomass billion $ 5.1 6.4 9.8 hydro billion $ 21.8 22.6 17.7 wind billion $ 25.1 108.8 99.9 pv billion $ 59.4 152.4 249.8 geothermal billion $ 0.6 36.8 36.9 solar thermal power plants billion $ 66.6 462.1 479.0 ocean energy billion $ 9.2 29.7 36.0 adv e[r] fossil (w/o chp) billion $ 66.0 33.1 93.4 nuclear billion $ 5.1 0.0 0.0 chp (fossil + renewable) billion $ 8.9 5.6 12.3 renewables (w/o chp) billion $ 205.1 1,071.5 1,408.5 total billion $ 285.1 1,110.3 1,514.1 conventional (fossil & nuclear) billion $ 76.1 35.1 96.5 renewables billion $ 209.1 1,075.2 1,417.6 biomass billion $ 5.1 6.4 9.2 hydro billion $ 21.8 22.4 17.7 wind billion $ 32.3 140.1 225.0 pv billion $ 59.4 244.9 262.7 geothermal billion $ 14.7 29.6 36.9 solar thermal power plants billion $ 66.6 602.1 787.5 ocean energy billion $ 9.2 29.7 78.6

20412050 144.7 8.6 3.9 108.1 265.3 156.6 108.7 9.0 20.8 47.8 17.4 0.0 13.7 0.0

2012unit 2050 493.8 billion $/a 43.9 billion $/a 10.4 billion $/a 286.9 billion $/a 834.9 billion $/a 547.0 billion $/a 288.0 billion $/a 17.0 billion $/a 82.8 billion $/a 78.7 billion $/a 43.8 billion $/a 0.0 billion $/a 65.7 billion $/a 0.0 billion $/a

annual average

40.2 0.0 9.2 1,218.0 1,267.4 42.1 1,225.3 10.3 20.8 190.2 316.6 5.1 645.5 36.8

229.0 billion $/a 5.1 billion $/a 36.0 billion $/a 3,137.0 billion $/a 3,407.1 billion $/a 246.0 billion $/a 3,161.1 billion $/a 31.5 billion $/a 82.8 billion $/a 424.1 billion $/a 778.2 billion $/a 79.4 billion $/a 1,653.2 billion $/a 111.8 billion $/a

5.9 0.1 0.9 80.4 87.4 6.3 81.1 0.8 2.1 10.9 20.0 2.0 42.4 2.9

0.0 0.0 9.2 1,787.4 1,796.6 1.9 1,794.7 9.5 20.8 217.7 358.4 48.2 1,085.3 54.9

192.5 billion $/a 5.1 billion $/a 36.0 billion $/a 4,472.5 billion $/a 4,706.2 billion $/a 209.6 billion $/a 4,496.6 billion $/a 30.1 billion $/a 82.7 billion $/a 615.1 billion $/a 925.4 billion $/a 129.4 billion $/a 2,541.4 billion $/a 172.5 billion $/a

4.9 0.1 0.9 114.7 120.7 5.4 115.3 0.8 2.1 15.8 23.7 3.3 65.2 4.4

2012-2050 12.7 1.1 0.3 7.4 21.4 14.0 7.4 0.4 2.1 2.0 1.1 0.0 1.7 0.0

[r]evolution

table 13.6.23: middle east: investments in renewable heat unit 20122021ref 2020 2030 heat pumps billion $ 0.0 0.0 deep geothermal billion $ 0.0 0.0 solar thermal billion $ 0.7 1.0 biomass billion $ 7.1 11.6 total billion $ 7.8 12.6 e[r] heat pumps billion $ 13.3 15.1 deep geothermal billion $ 24.3 14.4 solar thermal billion $ 16.3 37.5 bomass billion $ 13.6 5.9 total billion $ 67.5 72.9 adv e[r] heat pumps billion $ 13.3 15.1 deep geothermal billion $ 24.3 14.4 solar thermal billion $ 16.3 37.5 biomass billion $ 13.6 5.9 total billion $ 67.5 72.9

generation 203120412040 2050 0.0 0.0 0.0 0.0 1.7 2.4 15.6 21.0 17.4 23.4

2012unit 2050 0.0 billion $/a 0.0 billion $/a 5.8 billion $/a 55.3 billion $/a 61.2 billion $/a

annual average

45.2 28.7 49.7 14.5 138.1

82.8 33.8 27.5 10.5 154.6

156.4 billion $/a 101.2 billion $/a 131.0 billion $/a 44.5 billion $/a 433.1 billion $/a

4.0 2.6 3.4 1.1 11.1

45.2 28.7 49.7 14.5 138.1

82.8 33.8 67.3 10.5 194.5

156.4 billion $/a 101.2 billion $/a 170.9 billion $/a 44.5 billion $/a 473.0 billion $/a

4.0 2.6 4.4 1.1 12.1

table 13.6.24: middle east: total employment in the energy sector

thousand jobs adv e [ r ] scenariO

reference scenariO

2012-2050 0.0 0.0 0.1 1.4 1.6

2015 36 17 63 338 57.5 5 516

2020 41 17 76 384 58.7 5 581

2025 38 16 85 422 64.9 7 632

2030 32 12 87 436 66.3 5 638

2020 211 46 110 360 61.2 105 894

2025 371 72 181 335 45.9 107 1,112

2030 336 67 284 293 30.6 105 1,116

3 473 8 31 5 12 0.9 5.7 0.0 2.4 5 0.0 516

2 523 11 45 9 13 2.6 10 0.0 4.4 5 581

2 563 10 56 14 14 3.8 11.6 0.0 5.6 6.7 632

2 564 9 63 19 11 8.3 13.8 0.0 5.9 5.4 638

1 451 0 442 36 19 54 159 4.7 53 12 69 36 894

1 394 0 716 51 9 77 316 4.4 146 6 93 14 1,112

1 317 0 797 54 11 104 287 6 214 17 92 13 1,116

339

e a st e r n e u r o p e / e u r a s i a : r e f e r e n c e s c e n a r i o table 13.7.1 eastern europe/eurasia: electricity generation twh/a 2012 2020 810 974 82 61 69 76 62 136 0 0 7 3 3 3 297 333 0 12 283 326 5 16 0 0 1 5 0 3 0 0 0 0 933 975 175 187 91 91 635 677 0 0 30 19 1 2 0 0 0 0

864 69 1,743 1,155 257 160 697 37 3 297 0 0 291 283 5 1 1 0 0 0 184 294 0 0 1,254 7 0% 17%

899 76 1,949 1,252 248 166 813 22 3 333 0 0 363 326 16 5 13 3 0 0 211 296 0 0 1,434 21 1% 19%

2025 1,152 76 81 223 0 2 3 369 18 346 23 1 6 6 0 0 993 193 90 698 0 11 2 0 0

2030 1,329 90 87 307 0 2 3 405 24 367 29 2 7 8 0 0 1,014 199 89 720 0 3 2 0 0

2040 1,693 146 100 497 0 1 3 417 46 413 48 6 8 13 0 0 1,044 201 87 751 0 1 3 0 0

2050 2,067 282 113 614 0 0 2 430 69 458 67 10 11 20 0 0 1,075 202 85 785 0 0 4 0 0

912 81 2,146 1,376 269 171 920 13 3 369 0 0 400 346 23 6 20 6 0 0 234 308 0 0 1,595 29 1% 19%

926 88 2,343 1,500 289 176 1,027 5 3 405 0 0 437 367 29 7 26 8 0 0 258 320 0 0 1,757 36 2% 19%

945 99 2,737 1,787 347 187 1,249 2 3 417 0 0 532 413 48 8 49 13 0 0 303 366 0 0 2,060 57 2% 19%

963 112 3,142 2,083 484 198 1,399 0 2 430 0 0 629 458 67 11 73 20 0 0 353 376 0 0 2,405 78 2% 20%

table 13.7.2 eastern europe/eurasia: final energy consumption in transport pj/a 2012 2020 2025 2030 road 3,712 4,053 4,450 4,846 fossil fuels 3,666 3,971 4,297 4,623 biofuels 18 23 22 21 synfuels 0 0 0 0 natural gas 27 50 89 129 hydrogen 0 0 0 0 electricity 1 9 42 72 rail 591 635 658 682 fossil fuels 189 208 215 222 biofuels 0 0 0 0 synfuels 0 0 0 0 electricity 401 427 442 460 navigation 45 66 68 71 fossil fuels 45 66 68 71 biofuels 0 0 0 0 synfuels 0 0 0 0 aviation 297 337 360 382 fossil fuels 297 337 360 382 biofuels 0 0 0 0 synfuels 0 0 0 0 total (incl. pipelines) 6,012 6,471 6,929 7,388 fossil fuels 4,198 4,582 4,940 5,299 biofuels (incl. biogas) 18 23 22 21 synfuels 0 0 0 0 natural gas 1,393 1,429 1,483 1,536 hydrogen 0 0 0 0 electricity 402 436 484 532 total res 86 104 112 121 res share 1% 2% 2% 2%

2040 5,404 5,024 21 0 214 0 145 732 234 0 0 497 72 72 0 0 429 429 0 0 8,072 5,759 21 0 1,649 0 642 146 2%

table 13.7.3 eastern europe/eurasia: heat supply pj/a 2012 4,069 4,002 66 0 0 4,031 4,015 16 0 0 9,640 8,397 427 4 0 5 807 0 17,740 16,414 509 4 0 5 807 0 4%

2040 4,866 4,699 167 0 0 4,004 3,977 27 0 0 15,213 13,336 996 10 0 12 859 0 24,084 22,013 1,190 10 0 12 859 0 6%

2020 3,832 3,746 85 0 0 4,045 4,025 20 0 0 11,543 9,997 710 6 0 7 824 0 19,420 17,768 816 6 0 7 824 0 5%

2025 4,132 4,027 104 0 0 4,027 4,005 22 0 0 12,475 10,851 777 7 0 8 832 0 20,633 18,883 904 7 0 8 832 0 5%

2030 4,431 4,305 125 0 0 4,033 4,010 24 0 0 13,431 11,727 846 8 0 9 841 0 21,895 20,042 995 8 0 9 841 0 5%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

340

2050 5,515 4,956 20 0 303 0 236 777 244 0 0 533 75 75 0 0 474 474 0 0 8,305 5,749 20 0 1,768 0 769 174 2%

2050 5,295 5,082 213 0 0 4,016 3,985 31 0 0 17,196 15,115 1,176 14 0 15 876 0 26,507 24,181 1,421 14 0 15 876 0 6%

table 13.7.4: eastern europe/eurasia: installed capacity gw 2012 2020 total generation 432 476 fossil 290 310 hard coal (& non-renewable waste) 68 65 lignite 42 43 gas (w/o h2) 157 185 oil 21 15 diesel 2 2 nuclear 43 47 hydrogen (fuel cells, gas power plants, gas chp) 0 0 renewables 99 119 hydro 93 103 wind 4 8 of which wind offshore 0 0 pv 1 4 biomass (& renewable waste) 1 3 geothermal 0 0 solar thermal power plants 0 0 ocean energy 0 0 fluctuating res (pv, wind, ocean) 5 13 share of fluctuating res 1% 3% res share (domestic generation) 23% 25% table 13.7.5: eastern europe/eurasia: final energy demand pj/a 2012 2020 total (incl. non-energy use) 31,063 34,176 total energy use1 27,438 30,457 transport 6,012 6,471 oil products 4,198 4,582 natural gas 1,393 1,429 biofuels 18 23 synfuels 0 0 electricity 402 436 RES electricity 67 81 hydrogen 0 0 res share transport 1% 2% industry 9,526 10,982 electricity 2,009 2,320 RES electricity 336 433 public district heat 2,403 2,413 RES district heat 12 30 hard coal & lignite 1,448 2,003 oil products 789 866 gas 2,826 3,270 solar 0 0 biomass 51 111 geothermal 0 0 hydrogen 0 0 res share industry 4% 5% other sectors 11,901 13,004 electricity 2,104 2,406 RES electricity 351 449 public district heat 4,122 4,013 RES district heat 21 50 hard coal & lignite 467 465 oil products 1,077 1,078 gas 3,604 4,212 solar 4 5 biomass 519 821 geothermal 4 5 hydrogen 0 0 res share other sectors 8% 10% total res 1,383 2,008 res share 5% 7% non energy use 3,624 3,719 oil 1,825 1,873 gas 1,771 1,817 coal 28 29

2025 508 327 66 42 207 9 2 52 0 129 108 11 0 5 4 1 0 0 16 3% 25%

2025 36,582 32,602 6,929 4,940 1,483 22 0 484 90 0 2% 11,858 2,568 479 2,529 36 2,131 879 3,604 0 148 0 0 6% 13,814 2,691 502 4,143 59 478 1,061 4,573 6 856 6 0 10% 2,206 7% 3,980 2,004 1,945 31

2030 539 344 67 41 229 4 2 56 0 139 114 13 1 6 5 1 0 0 19 4% 26%

2030 38,938 34,747 7,388 5,299 1,536 21 0 532 99 0 2% 12,734 2,816 526 2,645 43 2,258 892 3,938 0 184 0 0 6% 14,624 2,976 555 4,274 70 491 1,043 4,935 7 891 6 0 10% 2,404 7% 4,191 2,110 2,048 33

2040 612 391 71 38 277 2 3 57 0 164 125 20 2 7 9 2 0 0 28 5% 27%

2050 681 431 94 38 297 0 2 59 0 191 139 27 3 9 13 3 0 0 36 5% 28%

2040 42,623 38,328 8,072 5,759 1,649 21 0 642 125 0 2% 14,078 3,252 632 2,765 56 2,437 870 4,493 1 261 0 0 7% 16,178 3,523 685 4,490 91 495 997 5,691 10 964 9 0 11% 2,854 7% 4,295 2,163 2,099 33

2050 46,114 41,764 8,305 5,749 1,768 20 0 769 154 0 2% 15,557 3,742 749 2,886 71 2,571 849 5,151 1 358 0 0 8% 17,902 4,147 830 4,714 115 493 952 6,530 13 1,042 11 0 11% 3,364 8% 4,350 2,190 2,125 34

1 excluding heat produced by chp autoproducers

table 13.7.6: eastern europe/eurasia: cO2 emissions mill t/a 2012 condensation power plants 208 hard coal (& non-renewable waste) 80 lignite 83 gas 36 oil 5 diesel 3 combined heat and power plants 853 hard coal (& non-renewable waste) 220 lignite 126 gas 476 oil 30 co2 emissions power and chp plants 1,060 hard coal (& non-renewable waste) 300 lignite 210 gas 512 oil & diesel 39 co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation 918 co2 intensity total electr. generation 608 co2 emissions by sector 2,713 % of 1990 emissions (3,986 mill t) 69% industry1 415 other sectors1 322 transport 304 power generation2 977 other conversion3 694 population (mill.) 341 co2 emissions per capita (t/capita) 8.0

2020 252 65 97 82 4 3 801 227 123 434 17 1,052 292 220 516 24

2025 318 80 102 130 4 3 769 227 120 411 10 1,086 307 222 541 17

2030 380 93 107 174 4 3 743 229 118 392 3 1,123 322 225 566 10

2040 553 143 117 290 1 2 692 223 113 355 1 1,245 365 230 645 5

2050 730 264 126 338 0 2 652 216 108 328 0 1,382 480 234 666 2

840 540 2,803 71% 484 355 333 980 651 341 8.2

789 506 2,921 74% 509 374 361 1,020 658 339 8.6

748 479 3,040 77% 537 393 388 1,059 662 335 9.1

697 455 3,298 83% 575 431 426 1,188 678 326 10.1

664 440 3,560 90% 617 473 430 1,329 711 316 11.3

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.7.7: eastern europe/eurasia: primary energy demand pj/a 2012 2020 total 49,312 50,888 fossil 44,261 44,663 hard coal (& non-renewable waste) 7,500 7,412 lignite 2,371 2,458 natural gas 23,864 24,553 crude oil 10,526 10,240 nuclear 3,266 3,651 renewables 1,784 2,574 hydro 1,019 1,174 wind 19 59 solar 9 23 biomass (& renewable waste) 717 1,223 geothermal 21 96 ocean energy 0 0 of which non-energy use 3,624 3,719 net electricity imports (final energy) -38 -30 total res incl. net electricity import 1,778 2,568 res share 4% 5%

2025 53,535 46,620 7,722 2,496 26,030 10,372 4,042 2,873 1,247 82 27 1,373 143 0 3,980 -29 2,868 5%

2030 56,178 48,575 8,027 2,538 27,508 10,503 4,433 3,170 1,321 106 32 1,523 188 0 4,191 -29 3,165 6%

2040 61,337 52,874 8,707 2,596 31,129 10,442 4,566 3,897 1,486 173 41 1,926 271 0 4,295 -29 3,891 6%

2050 66,227 56,851 10,095 2,654 33,800 10,303 4,702 4,675 1,651 241 52 2,357 373 1 4,350 -29 4,669 7%

e a st e r n e u r o p e / e u r a s i a : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.7.8 eastern europe/eurasia: electricity generation twh/a 2012 2020 810 927 82 43 69 43 62 170 0 0 7 3 3 3 297 269 0 23 283 326 5 36 0 1 1 8 0 4 0 0 0 0 933 976 175 164 91 80 635 669 0 0 30 14 1 49 0 0 0 0

864 69 1,743 1,155 257 160 697 37 3 297 0 0 291 283 5 1 1 0 0 0 184 294 0 0 1,254 7 0% 17%

899 77 1,903 1,188 207 123 838 17 3 269 0 0 447 326 36 8 72 4 0 0 206 294 0 0 1,404 44 2% 23%

2025 1,132 37 33 189 0 1 3 230 39 346 193 17 48 10 1 1 989 136 51 691 0 5 97 10 0

2030 1,387 38 15 209 0 0 3 150 41 360 415 48 123 24 5 5 1,001 85 18 711 0 0 151 36 0

2040 1,962 15 0 226 0 0 2 0 40 375 892 161 285 76 26 24 1,012 0 0 609 26 0 288 114 0

2050 2,336 0 0 81 0 0 1 0 21 380 1,256 240 410 104 40 44 966 0 0 389 79 0 384 186 6

903 86 2,121 1,145 173 84 880 5 3 230 0 0 746 346 193 48 136 20 1 1 234 293 1 0 1,593 242 11% 35%

903 98 2,388 1,078 122 33 920 0 3 150 0 0 1,160 360 415 123 191 60 5 5 268 288 7 0 1,825 543 23% 49%

888 124 2,973 826 15 0 809 0 2 0 27 19 2,120 375 892 285 328 190 26 24 328 224 190 0 2,232 1,201 40% 72%

829 137 3,302 392 0 0 391 0 1 0 85 75 2,825 380 1,256 410 405 290 40 44 347 124 468 0 2,363 1,710 52% 88%

table 13.7.9 eastern europe/eurasia: final energy consumption in transport pj/a 2012 2020 2025 2030 road 3,712 4,013 4,146 4,151 fossil fuels 3,666 3,848 3,683 3,285 biofuels 18 99 277 491 synfuels 0 0 0 0 natural gas 27 53 100 107 hydrogen 0 0 2 19 electricity 1 13 85 249 rail 591 639 655 685 fossil fuels 189 193 171 129 biofuels 0 10 9 31 synfuels 0 0 0 0 electricity 401 436 475 525 navigation 45 66 66 65 fossil fuels 45 63 63 59 biofuels 0 3 3 6 synfuels 0 0 0 0 aviation 297 337 343 347 fossil fuels 297 337 333 327 biofuels 0 0 10 21 synfuels 0 0 0 0 total (incl. pipelines) 6,012 6,289 6,306 6,206 fossil fuels 4,198 4,441 4,249 3,800 biofuels (incl. biogas) 18 112 299 548 synfuels 0 0 0 0 natural gas 1,393 1,281 1,177 1,027 hydrogen 0 0 2 19 electricity 402 455 578 812 total res 86 219 503 952 res share 1% 3% 8% 15%

2040 3,729 1,972 526 0 129 209 894 740 86 34 0 620 61 49 12 0 357 286 71 0 5,570 2,393 643 0 681 209 1,644 1,976 35%

table 13.7.10 eastern europe/eurasia: heat supply pj/a 2012 4,069 4,002 66 0 0 4,031 4,015 16 0 0 9,640 8,397 427 4 0 5 807 0 17,740 16,414 509 4 0 5 807 0 4%

2040 3,535 1,326 1,220 495 495 4,109 1,994 1,194 832 89 9,371 2,865 1,633 1,520 142 1,272 1,882 57 17,016 6,185 4,047 2,015 1,469 1,272 1,882 146 61%

2020 3,756 3,473 275 4 4 4,050 3,852 197 0 0 11,065 9,126 961 54 0 46 877 0 18,871 16,452 1,434 58 4 46 877 0 9%

2025 4,065 3,314 568 102 81 3,978 3,513 393 73 0 10,690 7,874 1,227 259 8 181 1,141 0 18,734 14,701 2,188 361 162 181 1,141 0 18%

2030 4,044 2,847 793 243 162 3,970 3,089 615 266 0 10,312 6,335 1,442 597 39 455 1,443 0 18,326 12,272 2,850 840 467 455 1,443 0 29%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2050 2,648 451 475 0 111 445 1,166 780 52 28 0 700 57 37 20 0 365 237 128 0 4,250 777 650 0 211 445 2,166 2,943 69%

2050 2,558 256 1,113 550 639 4,275 1,008 1,617 1,358 292 7,933 589 1,635 1,721 167 1,630 2,042 150 14,766 1,852 4,365 2,271 2,165 1,630 2,042 442 86%

table 13.7.10: eastern europe/eurasia: installed capacity gw 2012 2020 total generation 432 473 fossil 290 290 hard coal (& non-renewable waste) 68 54 lignite 42 32 gas (w/o h2) 157 191 oil 21 12 diesel 2 2 nuclear 43 38 hydrogen (fuel cells, gas power plants, gas chp) 0 0 renewables 99 145 hydro 93 103 wind 4 18 of which wind offshore 0 0 pv 1 7 biomass (& renewable waste) 1 16 geothermal 0 1 solar thermal power plants 0 0 ocean energy 0 0 fluctuating res (pv, wind, ocean) 5 25 share of fluctuating res 1% 5% res share (domestic generation) 23% 31% table 13.7.12: eastern europe/eurasia: final energy demand pj/a 2012 2020 total (incl. non-energy use) 31,063 33,152 total energy use1 27,438 29,470 transport 6,012 6,289 oil products 4,198 4,441 natural gas 1,393 1,281 biofuels 18 112 synfuels 0 0 electricity 402 455 RES electricity 67 107 hydrogen 0 0 res share transport 1% 3% industry 9,526 10,598 electricity 2,009 2,240 RES electricity 336 525 public district heat 2,403 2,412 RES district heat 23 154 hard coal & lignite 1,448 1,631 oil products 789 697 gas 2,826 3,187 solar 0 16 biomass 51 410 geothermal 0 5 hydrogen 0 0 res share industry 4% 10% other sectors 11,901 12,583 electricity 2,104 2,358 RES electricity 351 553 public district heat 4,122 3,977 RES district heat 40 253 hard coal & lignite 467 416 oil products 1,077 786 gas 3,604 4,128 solar 4 39 biomass 519 852 geothermal 4 27 hydrogen 0 0 res share other sectors 8% 14% total res 1,414 3,053 res share 5% 10% non energy use 3,624 3,682 oil 1,825 1,804 gas 1,771 1,841 coal 28 37

2025 571 267 43 21 198 4 2 32 0 272 108 91 5 42 27 3 0 1 133 23% 48%

2025 33,033 29,252 6,306 4,249 1,177 299 0 578 203 2 8% 10,599 2,510 882 2,535 397 1,133 504 3,153 118 611 36 0 19% 12,347 2,647 931 4,059 636 234 353 3,838 142 976 100 0 23% 5,331 18% 3,781 1,607 1,985 189

2030 723 245 29 9 205 0 2 21 0 457 111 187 15 107 39 8 1 2 297 41% 63%

2030 32,491 28,635 6,206 3,800 1,027 548 0 812 395 19 15% 10,550 2,818 1,369 2,557 679 633 307 3,087 236 806 107 0 30% 11,879 2,939 1,427 4,017 1,066 53 220 2,999 361 1,032 259 0 35% 8,293 29% 3,856 1,349 2,121 386

2040 1,071 224 8 0 214 0 2 0 7 839 114 370 50 246 67 26 5 11 627 59% 78%

2040 29,761 26,110 5,570 2,393 681 643 0 1,644 1,183 209 35% 9,467 3,175 2,284 2,322 1,346 0 98 2,028 496 962 324 62 58% 11,073 3,216 2,314 3,926 2,276 0 66 1,041 1,024 1,049 751 0 67% 14,846 57% 3,651 876 2,154 621

2050 1,334 179 0 0 178 0 1 0 35 1,119 115 506 72 342 90 40 8 18 866 65% 84%

2050 25,594 22,114 4,250 777 211 650 0 2,166 1,902 445 69% 7,614 3,074 2,699 2,078 1,737 0 6 394 528 1,000 375 158 85% 10,250 3,267 2,868 3,498 2,923 0 16 316 1,193 946 1,014 0 87% 18,365 83% 3,480 557 2,192 731

1 excluding heat produced by chp autoproducers

table 13.7.13: eastern europe/eurasia: cO2 emissions mill t/a 2012 2020 condensation power plants 209 208 hard coal (& non-renewable waste) 80 46 lignite 83 55 gas 36 102 oil 5 4 diesel 3 3 combined heat and power plants 853 745 hard coal (& non-renewable waste) 220 197 lignite 126 108 gas 476 427 oil 30 13 co2 emissions power and chp plants 1,060 954 hard coal (& non-renewable waste) 300 243 lignite 210 163 gas 512 529 oil & diesel 39 20 co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation 918 804 co2 intensity total electr. generation 608 502 co2 emissions by sector 2,713 2,571 % of 1990 emissions (3,986 mill t) 69% 65% industry1 415 427 other sectors1 322 325 transport 304 323 power generation2 977 888 other conversion3 694 609 population (mill.) 341 341 co2 emissions per capita (t/capita) 8.0 7.5

2025 194 39 42 110 1 3 633 159 67 402 4 827 198 109 512 8

2030 178 39 18 118 1 3 502 96 24 382 0 680 135 42 500 3

2040 149 15 0 131 1 2 272 0 0 272 0 421 15 0 404 3

2050 45 0 0 44 0 1 130 0 0 130 0 175 0 0 174 1

723 390 2,184 55% 356 261 311 770 486 339 6.5

631 285 1,769 45% 285 192 279 630 383 335 5.3

510 142 957 24% 147 74 179 376 180 326 2.9

446 53 317 8% 44 30 62 140 41 316 1.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.7.14: eastern europe/eurasia: primary energy 2012 total 49,312 fossil 44,261 hard coal (& non-renewable waste) 7,500 lignite 2,371 natural gas 23,864 crude oil 10,526 nuclear 3,266 renewables 1,784 hydro 1,019 wind 19 solar 9 biomass (& renewable waste) 717 geothermal 21 ocean energy 0 of which non-energy use 3,624 net electricity imports (final energy) -38 total res incl. net electricity import 1,778 res share 4%

demand pj/a 2020 2025 48,869 47,432 41,908 37,706 6,438 5,170 1,762 1,082 24,429 23,768 9,278 7,687 2,947 2,518 4,013 7,207 1,174 1,247 131 694 87 539 2,463 4,001 159 722 0 4 3,682 3,781 0 0 4,013 7,207 8% 15%

2030 45,451 32,479 3,636 418 22,158 6,267 1,642 11,330 1,296 1,495 1,301 5,344 1,875 18 3,856 0 11,330 25%

2040 41,072 20,374 1,205 0 15,560 3,609 0 20,699 1,350 3,213 3,135 7,277 5,637 86 3,651 0 20,699 50%

2050 34,810 9,260 731 0 7,124 1,405 0 25,549 1,368 4,522 3,890 7,723 7,888 158 3,480 0 25,549 73%

eastern europe/eurasia: advanced energy [r]evolution scenario table 13.7.15 eastern europe/eurasia: electricity generation twh/a 2012 2020 810 928 82 43 69 43 62 170 0 0 7 3 3 3 297 269 0 23 283 326 5 37 0 1 1 8 0 4 0 0 0 0 933 976 175 164 91 80 635 669 0 0 30 14 1 49 0 0 0 0

864 69 1,743 1,155 257 160 697 37 3 297 0 0 291 283 5 1 1 0 0 0 184 294 0 0 1,254 7 0% 17%

table 13.7.16 eastern europe/eurasia: final energy 2012 road 3,712 fossil fuels 3,666 biofuels 18 synfuels 0 natural gas 27 hydrogen 0 electricity 1 rail 591 fossil fuels 189 biofuels 0 synfuels 0 electricity 401 navigation 45 fossil fuels 45 biofuels 0 synfuels 0 aviation 297 fossil fuels 297 biofuels 0 synfuels 0 total (incl. pipelines) 6,012 fossil fuels 4,198 biofuels (incl. biogas) 18 synfuels 0 natural gas 1,393 hydrogen 0 electricity 402 total res 86 res share 1%

2030 1,619 11 15 209 4 0 3 150 41 360 579 127 181 54 9 7 1,001 85 18 711 14 0 151 36 0

2040 2,736 0 0 232 32 0 2 0 40 375 1,341 353 462 203 46 34 1,012 0 0 603 84 0 288 114 7

2050 4,025 0 0 154 154 0 0 0 19 380 2,205 570 780 367 60 60 956 0 0 316 316 0 393 222 25

903 86 2,187 1,137 169 84 876 5 3 230 4 2 816 346 229 66 136 37 1 1 234 293 47 0 1,614 296 14% 37%

903 98 2,620 1,033 95 33 902 0 3 150 19 10 1,418 360 579 181 191 91 9 7 268 288 153 0 1,910 767 29% 55%

888 124 3,747 721 0 0 718 0 2 0 124 99 2,903 375 1,341 462 328 317 46 34 328 224 712 25 2,459 1,837 49% 80%

829 127 4,980 0 0 0 0 0 0 0 495 495 4,485 380 2,205 780 412 589 60 60 347 124 1,820 144 2,545 3,045 61% 100%

consumption transport pj/a 2020 2025 2030 4,013 4,046 3,859 3,848 3,555 3,085 99 268 305 0 0 0 53 92 76 0 33 87 14 99 307 639 679 749 191 154 102 10 8 18 0 0 0 438 517 629 66 66 65 63 63 56 3 3 9 0 0 0 337 336 330 337 326 287 0 9 43 0 0 0 6,246 6,137 5,833 4,439 4,098 3,530 112 288 375 0 0 0 1,238 1,065 829 0 33 87 458 653 1,013 220 545 974 4% 9% 17%

table 13.7.17 eastern europe/eurasia: heat supply pj/a 2012 4,069 4,002 66 0 0 4,031 4,015 16 0 0 9,640 8,397 427 4 0 5 807 0 17,740 16,414 509 4 0 5 807 0 4%

899 77 1,904 1,188 207 123 838 17 3 269 0 0 447 326 37 8 72 4 0 0 206 294 0 0 1,404 45 2% 23%

2025 1,198 33 33 189 1 1 3 230 39 346 229 32 66 27 1 1 989 136 51 691 3 5 97 10 0

2020 3,756 3,473 275 4 4 4,050 3,852 197 0 0 11,065 9,126 961 54 0 46 877 0 18,871 16,452 1,434 58 4 46 877 0 9%

2025 4,065 3,314 568 102 81 3,978 3,500 393 73 13 10,690 7,844 1,227 259 8 181 1,141 31 18,734 14,658 2,188 361 162 181 1,141 44 18%

2030 4,044 2,847 793 243 162 3,971 3,036 615 266 54 10,311 6,227 1,441 597 39 455 1,443 108 18,326 12,110 2,849 839 467 455 1,443 162 30%

2040 3,012 1,215 493 28 32 354 919 910 43 27 2 838 61 40 20 1 311 202 103 6 4,789 1,500 643 37 240 354 2,016 2,571 54%

2040 3,527 1,323 1,217 494 494 4,129 1,764 1,194 836 335 9,358 2,291 1,631 1,518 141 1,392 2,028 357 17,015 5,378 4,042 2,012 1,471 1,392 2,028 692 66%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

342

2050 1,870 0 359 120 0 461 1,050 985 0 30 10 945 57 0 43 14 292 0 219 73 3,424 0 650 217 0 461 2,095 3,424 100%

2050 2,259 0 1,073 531 655 4,466 0 1,657 1,623 1,187 8,024 0 1,630 1,742 166 1,888 2,293 305 14,749 0 4,360 2,273 2,444 1,888 2,293 1,492 100%

table 13.7.18: eastern europe/eurasia: installed capacity gw 2012 2020 total generation 432 473 fossil 290 290 hard coal (& non-renewable waste) 68 54 lignite 42 32 gas (w/o h2) 157 191 oil 21 12 diesel 2 2 nuclear 43 38 hydrogen (fuel cells, gas power plants, gas chp) 0 0 renewables 99 145 hydro 93 103 wind 4 19 of which wind offshore 0 0 pv 1 7 biomass (& renewable waste) 1 16 geothermal 0 1 solar thermal power plants 0 0 ocean energy 0 0 fluctuating res (pv, wind, ocean) 5 26 share of fluctuating res 1% 5% res share (domestic generation) 23% 31% table 13.7.19: eastern europe/eurasia: final energy demand pj/a 2012 2020 total (incl. non-energy use) 31,063 33,109 total energy use1 27,438 29,427 transport 6,012 6,246 oil products 4,198 4,439 natural gas 1,393 1,238 biofuels 18 112 synfuels 0 0 electricity 402 458 RES electricity 67 107 hydrogen 0 0 res share transport 1% 4% industry 9,526 10,598 electricity 2,009 2,240 RES electricity 336 526 public district heat 2,403 2,412 RES district heat 23 154 hard coal & lignite 1,448 1,631 oil products 789 697 gas 2,826 3,187 solar 0 16 biomass 51 410 geothermal 0 5 hydrogen 0 0 res share industry 4% 10% other sectors 11,901 12,583 electricity 2,104 2,358 RES electricity 351 554 public district heat 4,122 3,977 RES district heat 40 253 hard coal & lignite 467 416 oil products 1,077 786 gas 3,604 4,128 solar 4 39 biomass 519 852 geothermal 4 27 hydrogen 0 0 res share other sectors 8% 14% total res 1,414 3,055 res share 5% 10% non energy use 3,624 3,682 oil 1,825 1,804 gas 1,771 1,841 coal 28 37

2025 602 265 42 21 197 4 2 32 1 304 108 106 10 57 27 5 0 1 163 27% 50%

2025 32,864 29,083 6,137 4,098 1,065 288 0 653 244 33 9% 10,599 2,510 938 2,535 399 1,133 504 3,137 118 611 36 16 20% 12,347 2,647 989 4,059 638 234 353 3,819 142 976 100 19 23% 5,503 19% 3,781 1,607 1,985 189

2030 838 234 22 9 201 0 2 21 4 578 111 252 40 157 39 13 2 3 413 49% 69%

2030 32,195 28,339 5,833 3,530 829 375 0 1,013 552 87 17% 10,569 2,845 1,551 2,557 687 633 302 3,022 236 806 107 61 32% 11,937 3,020 1,646 4,017 1,079 53 207 2,930 361 1,032 259 59 37% 8,803 31% 3,856 1,349 2,121 386

2040 1,468 237 0 0 235 0 2 0 40 1,190 114 542 109 399 67 44 10 16 956 65% 81%

2040 29,131 25,480 4,789 1,500 240 643 37 2,016 1,615 354 54% 9,492 3,359 2,691 2,318 1,386 0 90 1,653 495 960 349 268 64% 11,199 3,476 2,785 3,924 2,346 0 45 751 1,024 1,048 813 119 72% 16,778 66% 3,651 876 2,154 621

2050 2,054 0 0 0 0 0 0 0 261 1,793 115 869 170 600 91 81 12 25 1,494 73% 87%

2050 24,993 21,513 3,424 0 0 650 217 2,095 2,095 461 100% 7,673 3,332 3,332 2,073 2,073 0 0 0 555 998 395 321 100% 10,416 3,734 3,734 3,365 3,365 0 0 0 1,188 942 1,188 0 100% 21,513 100% 3,480 557 2,192 731

1 excluding heat produced by chp autoproducers

table 13.7.20 eastern europe/eurasia: cO2 emissions mill t/a 2012 condensation power plants 208 hard coal (& non-renewable waste) 80 lignite 83 gas 36 oil 5 diesel 3 combined heat and power plants 853 hard coal (& non-renewable waste) 220 lignite 126 gas 476 oil 30 co2 emissions power and chp plants 1,060 hard coal (& non-renewable waste) 300 lignite 210 gas 512 oil & diesel 39 co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation 918 co2 intensity total electr. generation 608 co2 emissions by sector 2,713 % of 1990 emissions (3,986 mill t) 69% industry1 415 other sectors1 322 transport 304 power generation2 977 other conversion3 694 population (mill.) 341 co2 emissions per capita (t/capita) 8.0

2020 209 46 55 102 4 3 745 197 108 427 13 954 243 163 529 20

2025 190 35 42 110 1 3 631 159 67 400 4 821 194 109 510 8

2030 149 11 18 116 1 3 494 96 24 374 0 643 108 42 490 3

2040 119 0 0 116 1 2 241 0 0 241 0 360 0 0 358 3

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

804 501 2,567 65% 427 325 322 888 605 341 7.5

722 375 2,156 54% 355 260 300 764 477 339 6.4

622 245 1,674 42% 280 187 258 594 355 335 5.0

500 96 742 19% 120 54 110 325 133 326 2.3

0 0 0 0% 0 0 0 0 0 316 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.7.21: eastern europe/eurasia: primary energy 2012 total 49,312 fossil 44,261 hard coal (& non-renewable waste) 7,500 lignite 2,371 natural gas 23,864 crude oil 10,526 nuclear 3,266 renewables 1,784 hydro 1,019 wind 19 solar 9 biomass (& renewable waste) 717 geothermal 21 ocean energy 0 of which non-energy use 3,624 net electricity imports (final energy) -38 total res incl. net electricity import 1,778 res share 4%

demand pj/a 2020 2025 48,776 47,536 41,820 37,241 6,232 4,822 1,762 1,082 24,549 23,822 9,276 7,515 2,947 2,518 4,009 7,777 1,174 1,247 133 824 87 601 2,457 3,974 159 1,127 0 4 3,682 3,781 0 0 4,009 7,777 8% 16%

2030 45,487 31,271 2,913 418 21,989 5,950 1,642 12,575 1,296 2,085 1,522 5,079 2,567 25 3,856 0 12,575 28%

2040 42,799 17,123 752 0 13,725 2,646 0 25,676 1,350 4,828 3,843 7,271 8,262 122 3,651 0 25,676 60%

2050 39,685 3,642 731 0 2,355 557 0 36,042 1,368 7,938 5,297 7,734 13,488 216 3,480 0 36,042 91%

energy

e a st e r n e u r o p e / e u r a s i a : e m p loy m e n t r e s u lts table 13.7.22: eastern europe/eurasia: investments in electricity generation unit 2012202120312041ref 2020 2030 2040 2050 fossil (w/o chp) billion $ 36.6 57.4 75.5 135.5 nuclear billion $ 52.2 70.4 39.3 55.8 chp (fossil + renewable) billion $ 166.0 101.1 43.7 7.5 renewables (w/o chp) billion $ 86.5 96.9 126.3 130.6 total billion $ 341.3 325.8 284.8 329.5 conventional (fossil & nuclear) billion $ 254.4 228.1 157.5 198.1 renewables billion $ 86.9 97.8 127.3 131.4 biomass billion $ 5.9 5.3 14.0 13.5 hydro billion $ 60.4 75.1 80.0 87.8 wind billion $ 9.4 9.8 22.5 20.2 pv billion $ 6.8 2.2 5.9 2.5 geothermal billion $ 4.4 5.4 4.9 7.4 solar thermal power plants billion $ 0.0 0.0 0.0 0.0 ocean energy billion $ 0.0 0.0 0.0 0.0 e[r] fossil (w/o chp) billion $ 29.6 15.1 29.5 25.0 nuclear billion $ 23.3 0.0 0.0 0.0 chp (fossil + renewable) billion $ 175.8 172.9 231.9 246.0 renewables (w/o chp) billion $ 114.0 529.1 653.4 749.3 total billion $ 342.7 717.2 914.8 1,020.3 conventional (fossil & nuclear) billion $ 193.8 79.9 56.6 26.5 renewables billion $ 148.9 637.3 858.1 993.8 biomass billion $ 46.0 70.8 134.1 153.0 hydro billion $ 60.4 69.3 53.9 52.3 wind billion $ 25.2 279.9 343.1 475.0 pv billion $ 11.4 130.9 148.9 153.6 geothermal billion $ 5.9 68.8 127.9 128.2 solar thermal power plants billion $ 0.0 5.9 21.3 13.9 ocean energy billion $ 0.0 11.7 28.9 17.9 adv e[r] fossil (w/o chp) billion $ 32.5 11.6 60.6 28.4 nuclear billion $ 23.3 0.0 0.0 0.0 chp (fossil + renewable) billion $ 175.8 172.8 231.3 285.1 renewables (w/o chp) billion $ 114.5 781.5 1,071.9 1,425.5 total billion $ 346.2 965.9 1,363.8 1,738.9 conventional (fossil & nuclear) billion $ 196.7 76.4 86.6 28.4 renewables billion $ 149.4 889.6 1,277.2 1,710.5 biomass billion $ 46.0 70.8 134.1 163.1 hydro billion $ 60.4 69.3 53.9 52.3 wind billion $ 25.8 424.8 552.3 916.2 pv billion $ 11.4 195.8 253.8 278.1 geothermal billion $ 5.9 101.9 204.6 264.8 solar thermal power plants billion $ 0.0 10.8 37.5 13.1 ocean energy billion $ 0.0 16.2 41.1 23.0

2012unit 2050 305.1 billion $/a 217.8 billion $/a 318.3 billion $/a 440.3 billion $/a 1,281.5 billion $/a 838.1 billion $/a 443.4 billion $/a 38.7 billion $/a 303.2 billion $/a 61.9 billion $/a 17.4 billion $/a 22.2 billion $/a 0.0 billion $/a 0.0 billion $/a

annual average

99.3 billion $/a 23.3 billion $/a 826.7 billion $/a 2,045.8 billion $/a 2,995.0 billion $/a 356.9 billion $/a 2,638.1 billion $/a 403.9 billion $/a 235.8 billion $/a 1,123.2 billion $/a 444.8 billion $/a 330.8 billion $/a 41.1 billion $/a 58.4 billion $/a

2.5 0.6 21.2 52.5 76.8 9.2 67.6 10.4 6.0 28.8 11.4 8.5 1.1 1.5

133.1 billion $/a 23.3 billion $/a 865.0 billion $/a 3,393.4 billion $/a 4,414.8 billion $/a 388.1 billion $/a 4,026.7 billion $/a 414.0 billion $/a 235.8 billion $/a 1,919.0 billion $/a 739.1 billion $/a 577.2 billion $/a 61.4 billion $/a 80.2 billion $/a

3.4 0.6 22.2 87.0 113.2 10.0 103.2 10.6 6.0 49.2 19.0 14.8 1.6 2.1

2012-2050 7.8 5.6 8.2 11.3 32.9 21.5 11.4 1.0 7.8 1.6 0.4 0.6 0.0 0.0

[r]evolution

table 13.7.23: eastern europe/eurasia: investments in renewable heat generation unit 20122021203120412012unit ref 2020 2030 2040 2050 2050 heat pumps billion $ 1.5 1.9 1.1 1.5 5.9 billion $/a deep geothermal billion $ 0.0 0.0 0.0 0.0 0.1 billion $/a solar thermal billion $ 0.6 0.7 0.7 0.7 2.7 billion $/a biomass billion $ 91.8 55.8 64.0 32.3 243.9 billion $/a total billion $ 93.9 58.3 65.8 34.6 252.6 billion $/a e[r] heat pumps billion $ 13.5 118.3 234.9 201.8 568.5 billion $/a deep geothermal billion $ 2.5 17.9 202.6 157.4 380.5 billion $/a solar thermal billion $ 10.5 123.5 182.0 131.1 447.1 billion $/a bomass billion $ 125.6 119.3 112.4 39.3 396.7 billion $/a total billion $ 152.2 378.9 731.9 529.7 1,792.7 billion $/a adv e[r] heat pumps billion $ 13.5 118.3 265.3 243.5 640.6 billion $/a deep geothermal billion $ 2.5 17.9 201.9 166.1 388.5 billion $/a solar thermal billion $ 10.5 123.5 181.6 133.0 448.6 billion $/a biomass billion $ 125.6 119.3 112.1 20.6 377.6 billion $/a total billion $ 152.2 378.9 760.9 563.3 1,855.3 billion $/a

table 13.7.24: eastern europe/eurasia total employment in the energy sector

2012-2050 0.2 0.0 0.1 6.3 6.5 14.6 9.8 11.5 10.2 46.0 16.4 10.0 11.5 9.7 47.6

thousand jobs adv e [ r ] scenariO

reference scenariO

annual average

2015 88 32 318 1,047 234.9 1 1,720

2020 104 40 336 838 288.1 2 1,609

2025 83 37 340 754 311.7 2 1,527

2030 81 42 319 707 334.3 2 1,485

2020 324 140 403 886 157.7 92 2,003

2025 685 364 557 844 142.5 437 3,030

2030 677 378 707 779 138.6 601 3,281

752 631 104 234 110 93 12 17.0 1.0 0.7 0.4 1,720

586 657 115 250 126 94 15.4 11.8 1.4 1.2 0.8 1,609

465 701 101 260 134 93 17.6 11.0 1.4 1.2 0.8 1,527

407 736 83 258 137 89 20.6 8.9 1.2 0.13 1.0 0.6 1,485

356 646 70 930 393 94 197 142 7 1.4 4 61 31 2,003

173 642 71 2,144 562 81 553 470 25 4.9 10.8 282 155 3,030

55 635 68 2,523 643 63 568 575 38 12.3 22.6 387 214 3,281

343

india: reference scenario table 13.8.4: india: installed capacity gw

table 13.8.1 india: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share (domestic generation)

2012 1,128 642 158 95 0 23 0 33 20 126 28 0 2 0 0 0 0 0 0 0 0 0 0 0 0

2020 1,734 993 228 145 0 19 0 64 42 162 60 0 21 0 0 0 0 0 0 0 0 0 0 0 0

2025 2,280 1,314 274 216 0 17 0 99 50 196 78 1 35 0 0 0 0 0 0 0 0 0 0 0 0

2030 2,826 1,625 328 287 0 15 0 134 59 231 96 3 49 1 0 0 0 0 0 0 0 0 0 0 0

2040 4,063 2,316 473 484 0 9 0 205 75 307 124 6 68 1 1 1 0 0 0 0 0 0 0 0 0

2050 5,184 2,957 624 601 0 5 0 277 92 383 152 9 91 1 1 1 0 0 0 0 0 0 0 0 0

0 0 1,128 919 642 158 95 23 0 33 0 0 176 126 28 2 20 0 0 0 193 71 0 0 869 30 3% 16%

0 0 1,734 1,385 993 228 145 19 0 64 0 0 286 162 60 21 42 0 0 0 288 153 0 0 1,298 81 5% 16%

0 0 2,280 1,820 1,314 274 216 17 0 99 0 0 361 196 78 35 50 0 0 0 379 198 0 0 1,709 113 5% 16%

0 0 2,826 2,256 1,625 328 287 15 0 134 0 0 436 231 96 49 59 1 0 0 470 242 0 0 2,119 145 5% 15%

0 0 4,063 3,282 2,316 473 484 9 0 205 0 0 576 307 124 68 75 1 1 1 676 341 0 0 3,051 192 5% 14%

0 0 5,184 4,187 2,957 624 601 5 0 277 0 0 721 383 152 91 92 1 1 1 878 351 0 0 3,961 244 5% 14%

table 13.8.2 india: final energy consumption in transport pj/a 2012 2020 road 2,811 4,490 fossil fuels 2,734 4,291 biofuels 9 48 synfuels 0 0 natural gas 69 150 hydrogen 0 0 electricity 0 1 rail 168 226 fossil fuels 112 151 biofuels 0 0 synfuels 0 0 electricity 56 75 navigation 29 57 fossil fuels 29 57 biofuels 0 0 synfuels 0 0 aviation 71 132 fossil fuels 71 132 biofuels 0 0 synfuels 0 0 total (incl. pipelines) 3,078 4,905 fossil fuels 2,945 4,631 biofuels (incl. biogas) 9 48 synfuels 0 0 natural gas 69 150 hydrogen 0 0 electricity 56 76 total res 17 60 res share 1% 1%

2025 6,326 6,004 79 0 240 0 3 261 181 0 0 81 72 72 0 0 175 175 0 0 6,834 6,431 79 0 240 0 84 92 1%

2030 8,147 7,702 109 0 330 0 5 297 211 0 0 86 92 92 0 0 227 227 0 0 8,762 8,232 109 0 330 0 91 123 1%

2040 13,031 12,269 284 0 458 0 20 356 266 0 0 90 132 132 0 0 379 379 0 0 13,898 13,045 284 0 458 0 110 300 2%

2050 17,844 16,677 504 0 620 0 45 387 300 0 0 87 170 170 0 0 632 632 0 0 19,033 17,779 504 0 620 0 131 522 3%

table 13.8.3 india: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 0 0 0 0 0 10,904 5,172 5,433 20 0 0 279 0 10,904 5,172 5,433 20 0 0 279 0 50%

2020 0 0 0 0 0 0 0 0 0 0 13,571 7,367 5,868 54 0 0 282 0 13,571 7,367 5,868 54 0 0 282 0 44%

2025 0 0 0 0 0 0 0 0 0 0 15,365 8,958 6,042 80 0 1 284 0 15,365 8,958 6,042 80 0 1 284 0 40%

2030 0 0 0 0 0 0 0 0 0 0 17,188 10,577 6,219 106 0 1 285 0 17,188 10,577 6,219 106 0 1 285 0 37%

2040 0 0 0 0 0 0 0 0 0 0 20,315 13,631 6,223 171 0 1 288 0 20,315 13,631 6,223 171 0 1 288 0 32%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

344

2050 0 0 0 0 0 0 0 0 0 0 24,268 17,380 6,334 261 0 2 291 0 24,268 17,380 6,334 261 0 2 291 0 27%

2012 235 162 106 26 23 7 0 5 0 68 42 18 0 1 6 0 0 0 20 8% 29%

2020 413 291 193 44 46 9 0 10 0 112 54 34 0 15 9 0 0 0 49 12% 27%

2025 554 397 267 56 65 8 0 14 0 143 65 42 0 25 11 0 0 0 67 12% 26%

2030 695 502 340 69 85 8 0 19 0 173 76 50 1 35 12 0 0 0 85 12% 25%

2040 985 729 495 101 127 6 0 29 0 226 101 62 2 47 15 0 0 0 109 11% 23%

2050 1,190 873 594 125 150 4 0 40 0 277 126 72 3 59 19 0 0 0 132 11% 23%

table 13.8.5: india: final energy demand pj/a total (incl. non-energy use) total energy use1 transport oil products natural gas biofuels synfuels electricity RES electricity hydrogen res share transport industry electricity RES electricity public district heat RES district heat hard coal & lignite oil products gas solar biomass geothermal hydrogen res share industry other sectors electricity RES electricity public district heat RES district heat hard coal & lignite oil products gas solar biomass geothermal hydrogen res share other sectors total res res share non energy use oil gas coal

2012 21,417 19,925 3,078 2,945 69 9 0 56 9 0 1% 7,034 1,381 216 0 0 2,926 789 684 1 1,254 0 0 21% 9,813 1,692 264 0 0 469 1,525 111 18 5,998 0 0 64% 7,769 39% 1,492 955 537 0

2020 28,467 26,362 4,905 4,631 150 48 0 76 13 0 1% 10,443 2,010 331 0 0 4,744 1,182 966 12 1,528 0 0 18% 11,014 2,588 426 0 0 483 1,600 124 42 6,176 0 0 60% 8,576 33% 2,105 1,347 758 0

2025 34,161 31,738 6,834 6,431 240 79 0 84 13 0 1% 12,814 2,535 401 0 0 5,819 1,385 1,299 19 1,759 0 0 17% 12,089 3,533 559 0 0 488 1,799 158 61 6,050 0 0 55% 8,940 28% 2,423 1,551 872 0

2030 39,855 37,113 8,762 8,232 330 109 0 91 14 0 1% 15,186 3,059 472 0 0 6,893 1,587 1,631 27 1,989 0 0 16% 13,165 4,478 690 0 0 494 1,998 192 80 5,923 1 0 51% 9,304 25% 2,741 1,755 987 0

2040 51,982 48,777 13,898 13,045 458 284 0 110 16 0 2% 19,767 4,221 598 0 0 8,810 1,978 2,279 41 2,437 0 0 16% 15,112 6,654 943 0 0 440 2,357 311 130 5,220 1 0 42% 9,670 20% 3,205 2,051 1,154 0

2050 64,887 61,219 19,033 17,779 620 504 0 131 18 0 3% 25,340 5,694 792 0 0 11,055 2,439 3,131 61 2,958 0 0 15% 16,846 8,434 1,173 0 0 390 2,763 475 200 4,582 1 0 35% 10,289 17% 3,668 2,347 1,320 0

1 excluding heat produced by chp autoproducers

table 13.8.6: india: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (580 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 1,039 774 199 41 24 0 0 0 0 0 0 1,039 774 199 41 24

2020 1,319 975 267 59 18 0 0 0 0 0 0 1,319 975 267 59 18

2025 1,647 1,238 308 86 16 0 0 0 0 0 0 1,647 1,238 308 86 16

2030 1,978 1,492 360 112 14 0 0 0 0 0 0 1,978 1,492 360 112 14

2040 2,786 2,089 509 180 8 0 0 0 0 0 0 2,786 2,089 509 180 8

2050 3,431 2,559 645 224 5 0 0 0 0 0 0 3,431 2,559 645 224 5

1,130 921 1,953 337% 356 158 216 1,039 185 1,237 1.6

952 760 2,620 452% 562 165 342 1,319 233 1,353 1.9

905 723 3,269 564% 691 182 476 1,647 273 1,419 2.3

877 700 3,918 675% 819 199 610 1,978 312 1,476 2.7

849 686 5,415 934% 1,054 226 964 2,786 386 1,566 3.5

820 662 6,802 1173% 1,333 260 1,313 3,431 464 1,620 4.2

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.8.7: india: primary energy demand pj/a 2012 total 32,941 fossil 24,270 hard coal (& non-renewable waste) 12,858 lignite 1,946 natural gas 2,049 crude oil 7,418 nuclear 359 renewables 8,312 hydro 453 wind 102 solar 27 biomass (& renewable waste) 7,730 geothermal 0 ocean energy 0 of which non-energy use 1,492 net electricity imports (final energy) 17 total res incl. net electricity import 8,315 res share 25%

2020 43,236 33,117 17,152 2,604 3,050 10,311 699 9,420 582 217 130 8,486 6 0 2,105 18 9,423 22%

2025 52,365 41,347 21,460 2,995 4,142 12,750 1,081 9,936 707 281 208 8,732 9 0 2,423 19 9,939 19%

2030 61,495 49,579 25,661 3,492 5,235 15,190 1,464 10,452 832 345 285 8,978 12 0 2,741 19 10,455 17%

2040 81,451 68,095 34,277 4,911 7,761 21,147 2,241 11,114 1,106 445 417 9,125 19 2 3,205 20 11,117 14%

2050 99,285 84,376 41,379 6,206 9,928 26,863 3,019 11,890 1,380 546 591 9,342 27 4 3,668 20 11,892 12%

energy

i n d i a : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.8.10: india: installed capacity gw

table 13.8.8 india: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share (domestic generation)

2012 1,128 642 158 95 0 23 0 33 20 126 28 0 2 0 0 0 0 0 0 0 0 0 0 0 0

2020 1,711 890 213 155 0 15 0 53 55 162 78 1 88 0 2 0 20 0 0 10 0 0 10 0 0

2025 2,230 854 213 287 0 14 0 48 70 196 305 32 214 6 21 3 66 0 0 30 0 0 33 4 0

2030 2,836 727 190 283 0 5 0 43 70 199 653 111 425 25 186 30 118 0 0 44 0 0 59 14 1

2040 4,277 396 90 259 0 0 0 24 69 205 1,451 292 921 157 615 90 307 0 0 74 0 0 154 62 17

2050 5,630 123 0 182 0 0 0 0 68 210 2,230 430 1,430 268 970 150 541 0 0 98 3 0 271 122 51

0 0 1,128 919 642 158 95 23 0 33 0 0 176 126 28 2 20 0 0 0 193 71 0 0 869 30 3% 16%

0 20 1,731 1,283 890 213 165 15 0 53 0 0 395 162 78 88 65 1 2 0 278 143 0 0 1,315 166 10% 23%

5 61 2,296 1,396 854 213 316 14 0 48 0 0 852 196 305 214 103 9 21 3 349 163 2 0 1,787 522 23% 37%

10 108 2,954 1,249 727 190 327 5 0 43 1 1 1,661 199 653 425 129 39 186 30 420 167 30 0 2,343 1,108 38% 56%

20 287 4,584 820 396 90 333 0 0 24 17 14 3,724 205 1,451 921 222 220 615 90 496 161 258 0 3,675 2,462 54% 82%

30 511 6,171 400 123 0 277 0 0 0 53 50 5,718 210 2,230 1,430 338 390 970 150 518 125 618 0 4,916 3,810 62% 93%

table 13.8.9 india: final energy consumption in transport pj/a 2012 2020 road 2,811 4,390 fossil fuels 2,734 4,149 biofuels 9 68 synfuels 0 0 natural gas 69 171 hydrogen 0 0 electricity 0 1 rail 168 228 fossil fuels 112 140 biofuels 0 7 synfuels 0 0 electricity 56 80 navigation 29 57 fossil fuels 29 54 biofuels 0 3 synfuels 0 0 aviation 71 132 fossil fuels 71 132 biofuels 0 0 synfuels 0 0 total (incl. pipelines) 3,078 4,807 fossil fuels 2,945 4,476 biofuels (incl. biogas) 9 78 synfuels 0 0 natural gas 69 171 hydrogen 0 0 electricity 56 82 total res 17 97 res share 1% 2%

2025 5,839 5,433 127 0 248 5 25 273 154 8 0 110 71 68 4 0 173 168 5 0 6,355 5,824 144 0 248 5 135 196 3%

2030 7,093 6,278 221 0 323 64 207 314 133 32 0 150 87 80 8 0 216 203 13 0 7,711 6,693 273 0 323 64 357 510 7%

2040 8,209 5,786 367 0 353 444 1,260 390 104 26 0 260 112 90 22 0 322 258 64 0 9,034 6,237 480 0 353 444 1,520 2,081 23%

2050 8,477 3,570 394 0 391 840 3,283 450 59 32 0 360 130 84 46 0 442 288 155 0 9,500 4,000 625 0 391 840 3,643 4,815 51%

table 13.8.10 india: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

[r]evolution

2012 0 0 0 0 0 0 0 0 0 0 10,904 5,172 5,433 20 0 0 279 0 10,904 5,172 5,433 20 0 0 279 0 50%

2020 0 0 0 0 0 84 35 45 4 0 13,216 6,882 5,787 82 0 7 457 0 13,300 6,917 5,832 82 4 7 457 0 45%

2025 38 0 29 9 1 283 103 148 32 0 14,054 6,813 5,779 514 30 112 806 0 14,375 6,916 5,955 522 63 112 806 0 49%

2030 129 0 91 32 6 550 153 265 123 8 14,955 6,368 5,549 1,145 124 387 1,381 0 15,633 6,521 5,905 1,177 254 387 1,381 8 55%

2040 414 0 186 182 46 1,628 254 694 558 123 15,512 4,637 4,800 2,209 274 800 2,751 41 17,555 4,891 5,680 2,391 878 800 2,751 164 69%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2050 796 0 199 470 127 3,010 329 1,222 1,089 371 14,289 1,765 3,902 2,850 509 1,216 3,804 242 18,096 2,094 5,323 3,320 1,725 1,216 3,804 614 87%

2012 235 162 106 26 23 7 0 5 0 68 42 18 0 1 6 0 0 0 20 8% 29%

table 13.8.12: india: final energy demand pj/a 2012 total (incl. non-energy use) 21,417 total energy use1 19,925 transport 3,078 oil products 2,945 natural gas 69 biofuels 9 synfuels 0 electricity 56 RES electricity 9 hydrogen 0 res share transport 1% industry 7,034 electricity 1,381 RES electricity 216 public district heat 0 RES district heat 0 hard coal & lignite 2,926 oil products 789 gas 684 solar 1 biomass 1,254 geothermal 0 hydrogen 0 res share industry 21% other sectors 9,813 electricity 1,692 RES electricity 264 public district heat 0 RES district heat 0 hard coal & lignite 469 oil products 1,525 gas 111 solar 18 biomass 5,998 geothermal 0 hydrogen 0 res share other sectors 64% total res 7,769 res share 39% non energy use 1,492 oil 955 gas 537 coal 0

2020 451 268 173 39 49 7 0 8 0 176 54 43 0 64 14 0 1 0 107 24% 39%

2020 27,719 25,656 4,807 4,476 171 78 0 82 19 0 2% 10,068 2,070 472 0 0 4,534 934 939 18 1,569 5 0 20% 10,781 2,584 590 0 0 473 1,454 176 64 6,030 0 0 62% 8,845 34% 2,063 1,320 743 0

2025 692 280 161 39 73 7 0 7 0 405 65 157 10 153 22 2 5 1 311 45% 59%

2025 31,452 29,150 6,355 5,824 248 144 0 135 50 5 3% 11,164 2,692 999 43 38 4,414 833 1,269 150 1,655 109 0 26% 11,630 3,607 1,338 7 6 385 1,212 244 364 5,812 0 0 65% 10,666 37% 2,302 1,404 783 115

2030 1,064 283 151 35 94 3 0 6 0 775 66 320 35 302 30 7 40 10 632 59% 73%

2040 1,815 256 120 19 116 0 0 3 5 1,551 68 667 87 576 51 36 125 28 1,271 70% 85%

2030 34,757 32,289 7,711 6,693 323 273 0 357 201 64 7% 12,196 3,386 1,905 124 115 4,272 576 1,337 497 1,612 391 0 37% 12,382 4,691 2,638 22 20 249 1,023 293 647 5,447 10 0 71% 13,793 43% 2,467 1,431 790 247

2040 38,487 35,731 9,034 6,237 353 480 0 1,520 1,239 444 23% 13,366 4,946 4,033 366 349 2,963 124 1,443 1,189 1,479 811 44 59% 13,331 6,765 5,515 68 65 80 540 384 1,019 4,425 50 0 83% 21,054 59% 2,756 1,378 827 551

2050 2,447 193 61 0 131 0 0 0 14 2,240 69 941 123 841 79 64 194 52 1,834 75% 92%

2050 38,599 35,599 9,500 4,000 391 625 0 3,643 3,405 840 51% 12,881 6,209 5,803 678 657 469 8 1,052 1,526 1,413 1,271 255 85% 13,219 7,845 7,332 132 128 0 23 511 1,325 3,233 149 0 92% 27,892 78% 3,000 1,110 840 1,050

1 excluding heat produced by chp autoproducers

table 13.8.13: india: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (580 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 1,039 774 199 41 24 0 0 0 0 0 0 1,039 774 199 41 24

2020 1,201 874 250 63 14 0 4 0 0 4 0 1,205 874 250 68 14

2025 1,170 805 239 113 13 0 13 0 0 13 0 1,184 805 239 127 13

2030 991 667 209 111 5 0 20 0 0 20 0 1,011 667 209 131 5

2040 551 357 97 97 0 0 34 0 0 34 0 585 357 97 130 0

2050 174 106 0 68 0 0 43 0 0 43 0 217 106 0 111 0

1,130 921 1,953 337% 356 158 216 1,039 185 1,237 1.6

939 696 2,441 421% 528 157 331 1,201 223 1,353 1.8

848 516 2,525 435% 535 135 433 1,171 250 1,419 1.8

809 342 2,359 407% 512 112 499 993 242 1,476 1.6

713 128 1,659 286% 379 68 468 555 188 1,566 1.1

543 35 780 134% 136 31 309 178 125 1,620 0.5

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.8.14: india: primary energy demand pj/a 2012 total 32,941 fossil 24,270 hard coal (& non-renewable waste) 12,858 lignite 1,946 natural gas 2,049 crude oil 7,418 nuclear 359 renewables 8,312 hydro 453 wind 102 solar 27 biomass (& renewable waste) 7,730 geothermal 0 ocean energy 0 of which non-energy use 1,492 net electricity imports (final energy) 17 total res incl. net electricity import 8,315 res share 25%

2020 41,230 31,046 15,698 2,436 3,334 9,578 578 9,606 582 282 406 8,317 20 0 2,063 18 9,610 23%

2025 45,623 32,913 14,708 2,294 5,344 10,566 521 12,188 707 1,100 1,367 8,688 316 11 2,302 19 12,192 27%

2030 48,485 31,437 12,931 1,957 5,769 10,780 467 16,581 716 2,351 3,378 8,804 1,222 108 2,467 19 16,590 34%

2040 52,474 23,865 7,784 909 6,258 8,913 260 28,349 738 5,224 7,921 8,920 5,222 324 2,756 20 28,365 54%

2050 52,420 13,506 2,708 0 5,400 5,398 0 38,914 756 8,030 11,961 8,932 8,695 540 3,000 20 38,933 74%

i n d i a : a d va n c e d e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.8.18: india: installed capacity gw

table 13.8.15 india: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share (domestic generation)

2012 1,128 642 158 95 0 23 0 33 20 126 28 0 2 0 0 0 0 0 0 0 0 0 0 0 0

2020 1,725 890 213 155 0 15 0 53 57 162 84 3 93 1 3 0 20 0 0 10 0 0 10 0 0

2025 2,324 828 213 287 1 14 0 48 65 196 406 57 233 11 22 3 66 0 0 30 0 0 33 4 0

2030 3,116 573 190 283 6 5 0 43 68 199 926 183 550 36 210 33 118 0 0 44 1 0 59 14 1

2040 5,397 142 90 260 36 0 0 24 70 205 2,269 430 1,325 199 714 100 307 0 0 74 10 0 154 62 17

2050 7,759 0 0 169 169 0 0 0 73 210 3,570 635 2,078 320 1,170 170 541 0 0 61 61 0 271 127 82

0 0 1,128 919 642 158 95 23 0 33 0 0 176 126 28 2 20 0 0 0 193 71 0 0 869 30 3% 16%

0 20 1,746 1,282 890 213 165 15 0 53 0 0 410 162 84 93 67 2 3 0 278 143 7 0 1,322 177 10% 23%

5 61 2,390 1,369 828 213 315 14 0 48 2 1 972 196 406 233 98 14 22 3 349 163 28 0 1,855 642 27% 41%

10 108 3,234 1,089 573 190 321 5 0 43 8 5 2,094 199 926 550 127 50 210 33 420 167 109 23 2,520 1,508 47% 65%

20 287 5,704 519 142 90 287 0 0 24 64 58 5,098 205 2,269 1,325 224 261 714 100 496 161 650 246 4,156 3,694 65% 90%

30 511 8,300 0 0 0 0 0 0 0 312 312 7,988 210 3,570 2,078 344 446 1,170 170 518 125 1,652 542 5,469 5,818 70% 100%

table 13.8.16 india: final energy consumption transport pj/a 2012 2020 road 2,811 4,356 fossil fuels 2,734 4,095 biofuels 9 67 synfuels 0 0 natural gas 69 169 hydrogen 0 18 electricity 0 9 rail 168 234 fossil fuels 112 129 biofuels 0 7 synfuels 0 0 electricity 56 99 navigation 29 57 fossil fuels 29 54 biofuels 0 3 synfuels 0 0 aviation 71 131 fossil fuels 71 131 biofuels 0 0 synfuels 0 0 total (incl. pipelines) 3,078 4,779 fossil fuels 2,945 4,409 biofuels (incl. biogas) 9 76 synfuels 0 0 natural gas 69 169 hydrogen 0 18 electricity 56 107 total res 17 106 res share 1% 2%

2025 5,595 5,131 120 0 212 52 81 325 131 7 0 186 71 68 4 0 168 163 5 0 6,159 5,493 135 0 212 52 267 265 4%

2030 6,432 5,420 223 27 212 194 383 450 105 17 2 327 87 76 11 1 201 175 23 3 7,196 5,775 273 33 212 194 709 881 12%

2040 5,557 2,422 389 292 57 1,013 1,676 894 47 18 13 816 112 73 22 17 251 163 50 38 7,107 2,705 480 360 57 1,013 2,492 3,973 56%

2050 4,629 0 434 567 0 1,224 2,971 1,342 0 20 25 1,297 130 0 56 74 265 0 115 150 6,934 0 625 816 0 1,224 4,268 6,934 100%

table 13.8.17 india: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 0 0 0 0 0 10,904 5,172 5,433 20 0 0 279 0 10,904 5,172 5,433 20 0 0 279 0 50%

2020 0 0 0 0 0 84 35 45 4 0 13,216 6,882 5,787 82 0 7 457 0 13,300 6,917 5,832 82 4 7 457 0 45%

2025 34 0 26 8 1 288 105 151 32 1 14,053 6,695 5,778 514 30 112 918 6 14,375 6,799 5,955 521 63 112 918 6 49%

2030 121 0 85 30 6 561 154 273 124 11 14,951 6,218 5,547 1,144 124 387 1,505 25 15,633 6,372 5,905 1,174 254 387 1,505 36 56%

2040 397 0 179 175 44 1,654 226 709 559 161 15,503 4,089 4,796 2,218 320 800 3,104 178 17,555 4,314 5,684 2,392 923 800 3,104 338 74%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

346

2050 756 0 189 446 121 3,191 0 1,251 1,136 805 14,147 0 3,876 2,989 726 1,199 4,616 741 18,095 0 5,316 3,436 1,982 1,199 4,616 1,546 100%

2012 235 162 106 26 23 7 0 5 0 68 42 18 0 1 6 0 0 0 20 8% 29%

table 13.8.19: india: final energy demand pj/a 2012 total (incl. non-energy use) 21,417 total energy use1 19,925 transport 3,078 oil products 2,945 natural gas 69 biofuels 9 synfuels 0 electricity 56 RES electricity 9 hydrogen 0 res share transport 1% industry 7,034 electricity 1,381 RES electricity 216 public district heat 0 RES district heat 0 hard coal & lignite 2,926 oil products 789 gas 684 solar 1 biomass 1,254 geothermal 0 hydrogen 0 res share industry 21% other sectors 9,813 electricity 1,692 RES electricity 264 public district heat 0 RES district heat 0 hard coal & lignite 469 oil products 1,525 gas 111 solar 18 biomass 5,998 geothermal 0 hydrogen 0 res share other sectors 64% total res 7,769 res share 39% non energy use 1,492 oil 955 gas 537 coal 0

2020 459 268 173 39 49 7 0 8 0 183 54 46 1 68 14 0 1 0 114 25% 40%

2020 27,690 25,628 4,779 4,409 169 76 0 107 25 18 2% 10,068 2,070 486 0 0 4,534 934 939 18 1,569 5 0 21% 10,781 2,584 607 0 0 473 1,454 176 64 6,030 0 0 62% 8,885 35% 2,063 1,320 743 0

2025 738 264 145 39 72 7 0 7 0 467 65 206 18 167 21 2 6 1 373 51% 63%

2025 31,237 28,935 6,159 5,493 212 135 0 267 109 52 4% 11,148 2,804 1,141 43 37 4,414 833 1,134 150 1,655 109 6 28% 11,629 3,607 1,468 7 6 385 1,211 243 364 5,811 0 1 66% 11,008 38% 2,302 1,404 783 115

2030 1,243 236 106 35 92 3 0 6 2 999 66 449 58 390 29 8 46 11 850 68% 80%

2040 2,409 166 43 19 103 0 0 3 21 2,218 68 1,048 128 828 54 43 146 31 1,907 79% 92%

2030 34,340 31,873 7,196 5,775 212 273 33 709 460 194 12% 12,201 3,540 2,298 124 113 4,272 571 1,170 497 1,612 391 24 40% 12,475 4,824 3,132 22 20 249 1,000 274 647 5,444 10 5 74% 15,062 47% 2,467 1,431 790 247

2040 36,805 34,049 7,107 2,705 57 480 360 2,492 2,252 1,013 56% 13,390 5,348 4,834 366 346 2,908 115 970 1,189 1,479 857 156 66% 13,552 7,122 6,437 68 64 68 503 257 1,028 4,419 50 36 89% 24,852 73% 2,756 1,378 827 551

2050 3,414 0 0 0 0 0 0 0 151 3,263 69 1,518 184 1,222 87 73 234 59 2,799 82% 96%

2050 36,162 33,162 6,934 0 0 625 816 4,268 4,268 1,224 100% 12,743 6,900 6,900 667 667 0 0 0 1,668 1,390 1,476 641 100% 13,485 8,520 8,520 132 132 0 0 0 1,321 3,224 149 139 100% 33,162 100% 3,000 1,110 840 1,050

1 excluding heat produced by chp autoproducers

table 13.8.20 india: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (580 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 1,039 774 199 41 24 0 0 0 0 0 0 1,039 774 199 41 24

2020 1,200 873 250 63 14 0 4 0 0 4 0 1,205 873 250 68 14

2025 1,145 780 239 113 13 0 13 0 0 13 0 1,158 780 239 126 13

2030 848 526 209 108 5 0 20 0 0 20 0 867 526 209 128 5

2040 308 128 97 83 0 0 29 0 0 29 0 337 128 97 112 0

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

1,130 921 1,953 337% 356 158 216 1,039 185 1,237 1.6

939 690 2,432 419% 528 157 326 1,200 220 1,353 1.8

846 485 2,454 423% 528 135 407 1,146 239 1,419 1.7

796 268 2,026 349% 503 110 427 849 137 1,476 1.4

650 59 952 164% 345 57 198 311 40 1,566 0.6

0 0 0 0% 0 0 0 0 0 1,620 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.8.21: india: primary energy demand pj/a 2012 total 32,941 fossil 24,270 hard coal (& non-renewable waste) 12,858 lignite 1,946 natural gas 2,049 crude oil 7,418 nuclear 359 renewables 8,312 hydro 453 wind 102 solar 27 biomass (& renewable waste) 7,730 geothermal 0 ocean energy 0 of which non-energy use 1,492 net electricity imports (final energy) 17 total res incl. net electricity import 8,315 res share 25%

2020 41,120 30,862 15,489 2,436 3,437 9,500 578 9,680 582 303 427 8,320 48 0 2,063 18 9,684 24%

2025 45,104 31,917 14,141 2,294 5,293 10,189 521 12,665 707 1,461 1,438 8,612 437 11 2,302 19 12,669 28%

2030 46,997 28,222 10,936 1,957 5,606 9,722 467 18,308 716 3,332 3,912 8,762 1,466 119 2,467 19 18,317 39%

2040 50,082 15,817 4,990 909 4,911 5,007 260 34,005 738 8,171 9,733 8,919 6,084 360 2,756 20 34,021 68%

2050 51,287 3,093 1,050 0 933 1,110 0 48,194 756 12,854 15,129 8,945 9,898 612 3,000 20 48,213 94%

energy

i n d i a : i n v e st m e n t a n d e m p loy m e n t table 13.8.22: india: investments in electricity generation unit 20122021ref 2020 2030 fossil (w/o chp) billion $ 215.3 354.3 nuclear billion $ 18.5 37.8 chp (fossil + renewable) billion $ 0.0 0.0 renewables (w/o chp) billion $ 109.8 153.0 total billion $ 343.6 545.1 conventional (fossil & nuclear) billion $ 233.8 392.1 renewables billion $ 109.8 153.0 biomass billion $ 10.2 13.3 hydro billion $ 43.1 72.8 wind billion $ 28.9 40.3 pv billion $ 27.5 26.4 geothermal billion $ 0.0 0.0 solar thermal power plants billion $ 0.1 0.3 ocean energy billion $ 0.0 0.0 e[r] fossil (w/o chp) billion $ 176.3 28.3 nuclear billion $ 13.0 0.0 chp (fossil + renewable) billion $ 8.3 53.4 renewables (w/o chp) billion $ 216.2 1,110.4 total billion $ 413.8 1,192.0 conventional (fossil & nuclear) billion $ 192.1 37.5 renewables billion $ 221.7 1,154.6 biomass billion $ 20.4 41.3 hydro billion $ 43.1 45.4 wind billion $ 43.8 478.1 pv billion $ 111.2 311.6 geothermal billion $ 0.9 52.5 solar thermal power plants billion $ 2.2 178.3 ocean energy billion $ 0.0 47.4 adv e[r] fossil (w/o chp) billion $ 176.0 26.4 nuclear billion $ 13.0 0.0 chp (fossil + renewable) billion $ 8.3 53.4 renewables (w/o chp) billion $ 232.5 1,476.8 total billion $ 429.8 1,556.6 conventional (fossil & nuclear) billion $ 191.8 35.5 renewables billion $ 237.9 1,521.0 biomass billion $ 21.3 39.3 hydro billion $ 43.1 45.4 wind billion $ 49.8 700.1 pv billion $ 117.5 418.6 geothermal billion $ 2.6 65.1 solar thermal power plants billion $ 3.5 200.5 ocean energy billion $ 0.0 52.0

20312040 418.6 44.6 0.0 181.7 644.9 463.2 181.7 17.9 84.0 50.7 28.2 0.3 0.3 0.4

20412050 487.1 51.0 0.0 187.3 725.4 538.1 187.3 19.5 87.1 54.2 24.9 0.4 0.7 0.5

2012unit 2050 1,475.3 billion $/a 151.9 billion $/a 0.0 billion $/a 631.7 billion $/a 2,259.0 billion $/a 1,627.3 billion $/a 631.7 billion $/a 60.8 billion $/a 287.1 billion $/a 174.0 billion $/a 107.0 billion $/a 0.7 billion $/a 1.3 billion $/a 0.9 billion $/a

annual average

24.9 0.0 118.3 1,567.8 1,711.0 34.4 1,676.6 67.0 21.7 618.3 344.7 190.1 368.3 66.6

114.3 0.0 169.0 1,782.8 2,066.0 127.6 1,938.4 99.1 21.5 875.6 393.9 177.1 314.7 56.6

343.7 billion $/a 13.0 billion $/a 348.9 billion $/a 4,677.2 billion $/a 5,382.8 billion $/a 391.5 billion $/a 4,991.3 billion $/a 227.8 billion $/a 131.8 billion $/a 2,015.9 billion $/a 1,161.4 billion $/a 420.6 billion $/a 863.4 billion $/a 170.5 billion $/a

8.8 0.3 8.9 119.9 138.0 10.0 128.0 5.8 3.4 51.7 29.8 10.8 22.1 4.4

25.3 0.0 118.3 2,242.7 2,386.3 34.8 2,351.5 75.3 21.7 1,011.4 516.9 218.6 433.4 74.2

131.7 0.0 168.1 2,565.2 2,864.9 137.9 2,727.0 106.7 21.5 1,377.3 560.3 195.5 399.6 66.0

359.4 billion $/a 13.0 billion $/a 348.0 billion $/a 6,517.1 billion $/a 7,237.5 billion $/a 400.1 billion $/a 6,837.4 billion $/a 242.7 billion $/a 131.8 billion $/a 3,138.6 billion $/a 1,613.2 billion $/a 481.8 billion $/a 1,037.1 billion $/a 192.3 billion $/a

9.2 0.3 8.9 167.1 185.6 10.3 175.3 6.2 3.4 80.5 41.4 12.4 26.6 4.9

2012-2050 37.8 3.9 0.0 16.2 57.9 41.7 16.2 1.6 7.4 4.5 2.7 0.0 0.0 0.0

[r]evolution

table 13.8.23: india: investments in renewable heat generation unit 201220212031ref 2020 2030 2040 heat pumps billion $ 0.1 0.2 0.2 deep geothermal billion $ 0.0 0.0 0.0 solar thermal billion $ 3.2 4.0 6.7 biomass billion $ 170.0 54.8 38.0 total billion $ 173.3 59.0 44.9 e[r] heat pumps billion $ 1.1 62.9 71.8 deep geothermal billion $ 0.0 25.2 48.5 solar thermal billion $ 5.2 105.5 144.0 bomass billion $ 105.6 26.7 5.5 total billion $ 111.9 220.3 269.8 adv e[r] heat pumps billion $ 1.1 62.9 71.8 deep geothermal billion $ 0.0 25.2 55.8 solar thermal billion $ 5.2 105.2 143.7 biomass billion $ 105.6 26.3 5.4 total billion $ 111.9 219.6 276.6

table 13.8.24: india: total employment in the energy sector

20412050 0.3 0.0 8.2 46.7 55.2

2012unit 2050 0.8 billion $/a 0.0 billion $/a 22.1 billion $/a 309.5 billion $/a 332.5 billion $/a

annual average

134.0 100.5 173.9 6.9 415.3

269.9 billion $/a 174.2 billion $/a 428.5 billion $/a 144.6 billion $/a 1,017.2 billion $/a

6.9 4.5 11.0 3.7 26.1

131.6 125.3 192.1 2.3 451.3

267.4 billion $/a 206.3 billion $/a 446.1 billion $/a 139.6 billion $/a 1,059.5 billion $/a

6.9 5.3 11.4 3.6 27.2

thousand jobs adv e [ r ] scenariO

reference scenariO

2012-2050 0.0 0.0 0.6 7.9 8.5

2015 1,226 628 414 2,265 20 4,554

2020 1,622 819 560 2,323 20 5,344

2025 1,427 719 654 2,211 23 5,035

2030 1,204 598 621 1,826 22 4,271

2020 1,459 1,691 780 2,304 50 6,284

2025 2,532 2,627 1,239 2,106 466 8,969

2030 2,283 2,395 1,625 1,540 733 8,576

2,252 224 84 1,993 1,515 146 131 177 1.6 3.0 19.7 4,554

2,769 299 118 2,158 1,584 204 143 203 1.2 2.6 19.4 0.4 5,344

2,552 362 133 1,989 1,433 198 142 189 0.9 2.4 0.01 22.8 0.3 5,035

2,324 343 120 1,483 1,076 170 103 109 0.6 1.8 1.1 22.2 0.3 4,271

839 319 31 5,095 1,688 204 1,409 1,606 25 75 39.0 45 5 6,284

618 437 26 7,889 1,659 80 2,513 2,742 46 287 95.7 382 83 8,969

384 357 18 7,817 1,312 64 2,662 2,365 73 479 128.7 549 185 8,576

347

ot h e r a s i a : r e f e r e n c e s c e n a r i o table 13.9.1 Other asia: electricity generation twh/a 2012 power plants 1,180 hard coal (& non-renewable waste) 203 lignite 143 gas 467 of which from H2 0 oil 84 diesel 32 nuclear 45 biomass (& renewable waste) 8 hydro 175 wind 2 of which wind offshore 0 pv 1 geothermal 20 solar thermal power plants 0 ocean energy 0 combined heat and power plants 39 hard coal (& non-renewable waste) 28 lignite 5 gas 4 of which from H2 0 oil 2 biomass (& renewable waste) 0 geothermal 0 hydrogen 0 CHP by producer main activity producers 8 autoproducers 31 total generation 1,219 fossil 969 hard coal (& non-renewable waste) 231 lignite 147 gas 471 oil 87 diesel 32 nuclear 45 hydrogen 0 of which renewable H2 0 renewables (w/o renewable hydrogen) 206 hydro 175 wind 2 pv 1 biomass (& renewable waste) 8 geothermal 20 solar thermal power plants 0 ocean energy 0 distribution losses 99 own consumption electricity 54 electricity for hydrogen production 0 electricity for synfuel production 0 final energy consumption (electricity) 1,081 fluctuating res (pv, wind, ocean) 3 share of fluctuating res 0% res share (domestic generation) 17%

table 13.9.2 Other asia: final energy consumption 2012 road 5,471 fossil fuels 5,143 biofuels 79 synfuels 0 natural gas 248 hydrogen 0 electricity 1 rail 65 fossil fuels 50 biofuels 0 synfuels 0 electricity 15 navigation 177 fossil fuels 177 biofuels 0 synfuels 0 aviation 172 fossil fuels 172 biofuels 0 synfuels 0 total (incl. pipelines) 5,886 fossil fuels 5,543 biofuels (incl. biogas) 79 synfuels 0 natural gas 248 hydrogen 0 electricity 15 total res 82 res share 1%

table 13.9.4: Other asia: installed capacity gw 2020 1,640 441 181 559 0 69 19 72 33 220 10 0 8 27 0 0 47 33 6 6 0 2 0 0 0

2025 2,021 647 201 643 0 55 14 75 47 267 24 1 14 33 0 0 50 34 6 8 0 2 0 0 0

2030 2,402 852 221 727 0 38 12 78 62 315 38 2 20 39 1 0 52 35 7 9 0 2 0 0 0

2040 3,487 1,454 260 1,037 0 14 8 56 90 396 82 7 33 55 1 0 57 37 7 11 0 2 0 0 0

2050 4,503 1,823 299 1,433 0 4 4 39 127 492 154 18 51 74 3 0 64 40 8 15 0 1 0 0 0

10 37 1,687 1,317 474 187 566 71 19 72 0 0 298 220 10 8 33 27 0 0 137 68 0 0 1,497 18 1% 18%

11 39 2,071 1,609 680 207 651 57 14 75 0 0 386 267 24 14 47 33 0 0 168 83 0 0 1,835 38 2% 19%

11 41 2,454 1,901 887 227 736 40 12 78 0 0 475 315 38 20 62 39 1 0 199 98 0 0 2,172 58 2% 19%

12 45 3,544 2,830 1,490 267 1,048 16 8 56 0 0 658 396 82 33 90 55 1 0 288 135 0 0 3,137 115 3% 19%

14 50 4,567 3,627 1,863 307 1,447 6 4 39 0 0 901 492 154 51 127 74 3 0 374 135 0 0 4,074 205 4% 20%

in transport pj/a 2020 2025 6,863 7,738 6,414 7,227 198 237 0 0 249 272 0 0 1 2 89 105 68 81 0 0 0 0 20 25 228 264 228 264 0 0 0 0 263 318 263 318 0 0 0 0 7,442 8,425 6,973 7,889 198 237 0 0 249 272 0 0 21 27 202 242 3% 3%

2030 8,601 8,029 274 0 295 0 3 122 93 0 0 29 300 300 0 0 384 384 0 0 9,407 8,806 274 0 295 0 32 280 3%

2040 10,138 9,264 381 0 489 0 5 159 118 0 0 42 372 372 0 0 507 507 0 0 11,177 10,261 381 0 489 0 46 390 3%

2050 10,927 9,702 457 0 759 0 8 199 142 0 0 56 444 444 0 0 652 652 0 0 12,222 10,941 457 0 759 0 64 470 4%

table 13.9.3 Other asia: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 105 105 0 0 0 10,247 5,167 4,215 4 0 0 861 0 10,352 5,272 4,215 4 0 0 861 0 42%

2020 0 0 0 0 0 141 141 0 0 0 12,398 6,953 4,509 26 0 0 910 0 12,539 7,094 4,509 26 0 0 910 0 37%

2025 0 0 0 0 0 164 164 0 0 0 13,751 8,147 4,583 41 0 0 980 0 13,915 8,311 4,583 41 0 0 980 0 35%

2030 0 0 0 0 0 190 190 0 0 0 15,144 9,367 4,651 55 0 0 1,070 0 15,333 9,557 4,651 55 0 0 1,070 0 32%

2040 0 0 0 0 0 268 268 0 0 0 18,719 12,563 4,820 96 0 0 1,240 0 18,988 12,831 4,820 96 0 0 1,240 0 27%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

348

2050 0 0 0 0 0 406 406 0 0 0 21,532 15,199 4,780 154 0 0 1,399 0 21,938 15,605 4,780 154 0 0 1,399 0 24%

2012 289 221 41 26 109 33 12 6 0 62 52 1 0 1 5 3 0 0 2 1% 21%

table 13.9.5: Other asia: final energy demand pj/a 2012 total (incl. non-energy use) 26,182 total energy use1 23,024 transport 5,886 oil products 5,543 natural gas 248 biofuels 79 synfuels 0 electricity 15 RES electricity 3 hydrogen 0 res share transport 1% industry 7,331 electricity 1,751 RES electricity 295 public district heat 9 RES district heat 0 hard coal & lignite 1,922 oil products 1,167 gas 1,433 solar 0 biomass 1,048 geothermal 0 hydrogen 0 res share industry 18% other sectors 9,807 electricity 2,125 RES electricity 358 public district heat 28 RES district heat 0 hard coal & lignite 183 oil products 1,328 gas 477 solar 4 biomass 5,663 geothermal 0 hydrogen 0 res share other sectors 61% total res 7,451 res share 32% non energy use 3,158 oil 2,489 gas 662 coal 7

2020 411 303 86 34 139 34 9 9 0 99 74 5 0 6 10 4 0 0 11 3% 24%

2020 31,750 28,234 7,442 6,973 249 198 0 21 4 0 3% 9,892 2,354 416 9 0 2,592 1,441 2,229 9 1,258 0 0 17% 10,900 3,014 533 35 0 222 1,397 677 17 5,537 0 0 56% 7,973 28% 3,516 2,701 767 48

2025 501 362 122 37 163 32 8 10 0 129 90 11 0 11 12 5 0 0 21 4% 26%

2025 35,545 31,690 8,425 7,889 272 237 0 27 5 0 3% 11,385 2,747 513 9 0 2,911 1,462 2,883 11 1,363 0 0 17% 11,880 3,831 715 42 0 264 1,483 858 30 5,372 0 0 51% 8,244 26% 3,855 2,944 858 53

2030 591 422 157 40 187 29 8 10 0 159 107 16 1 15 14 6 0 0 32 5% 27%

2030 39,340 35,137 9,407 8,806 295 274 0 32 6 0 3% 12,879 3,140 607 10 0 3,230 1,483 3,536 13 1,468 0 0 16% 12,851 4,649 899 48 0 307 1,560 1,040 42 5,206 0 0 48% 8,515 24% 4,202 3,191 954 57

2040 826 596 253 45 270 19 9 7 0 222 135 34 2 25 19 8 0 0 59 7% 27%

2040 48,317 43,545 11,177 10,261 489 381 0 46 9 0 3% 16,602 4,162 773 12 0 3,882 1,483 5,368 18 1,678 0 0 15% 15,767 7,083 1,315 68 0 453 1,748 1,494 78 4,841 0 0 40% 9,092 21% 4,772 3,579 1,127 65

2050 1,067 754 311 51 374 11 7 5 0 308 168 62 6 39 26 11 1 0 102 10% 29%

2050 55,148 50,151 12,222 10,941 759 457 0 64 13 0 4% 19,724 5,327 1,051 13 0 4,034 1,354 7,212 21 1,764 0 0 14% 18,205 9,275 1,830 84 0 654 1,835 1,916 133 4,307 0 0 34% 9,576 19% 4,997 3,700 1,228 68

1 excluding heat produced by chp autoproducers

table 13.9.6: Other asia: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (697 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 673 180 185 213 56 40 37 24 9 3 1 710 203 194 215 97

2020 915 392 196 249 55 23 46 30 11 4 1 961 422 208 253 79

2025 1,125 577 213 274 44 17 49 32 11 4 1 1,174 609 224 278 62

2030 1,335 763 228 299 31 14 52 35 12 5 1 1,387 798 240 304 46

2040 1,976 1,287 264 405 11 9 59 41 12 6 1 2,035 1,328 276 411 21

2050 2,483 1,606 303 566 3 4 70 49 13 7 1 2,553 1,655 316 573 9

733 582 1,741 250% 378 144 430 685 104 1,086 1.6

730 569 2,241 321% 511 164 537 930 98 1,193 1.9

729 567 2,618 376% 582 185 607 1,140 104 1,254 2.1

729 565 2,994 430% 652 204 677 1,351 110 1,308 2.3

719 574 3,999 574% 821 258 797 1,993 130 1,395 2.9

704 559 4,755 682% 936 306 863 2,503 146 1,449 3.3

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.9.7: Other asia: primary energy demand pj/a 2012 2020 total 35,534 43,459 fossil 26,189 32,914 hard coal (& non-renewable waste) 4,127 7,218 lignite 2,157 2,273 natural gas 7,732 9,223 crude oil 12,173 14,201 nuclear 491 788 renewables 8,854 9,757 hydro 630 791 wind 6 37 solar 8 56 biomass (& renewable waste) 7,502 8,101 geothermal 708 774 ocean energy 0 0 of which non-energy use 3,158 3,516 net electricity imports (final energy) 55 56 total res incl. net electricity import 8,863 9,767 res share 25% 22%

2025 48,947 37,914 9,602 2,420 10,660 15,231 821 10,212 963 87 92 8,260 810 0 3,855 56 10,222 21%

2030 54,578 43,022 11,995 2,561 12,204 16,262 854 10,701 1,135 137 129 8,422 878 0 4,202 56 10,712 20%

2040 68,905 56,500 18,504 2,881 17,206 17,909 614 11,791 1,427 296 220 8,754 1,094 0 4,772 57 11,801 17%

2050 79,542 66,497 22,415 3,214 22,354 18,514 430 12,615 1,771 553 348 8,603 1,341 0 4,997 57 12,626 16%

energy

ot h e r a s i a : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.9.8 Other asia: electricity generation twh/a 2012 power plants 1,180 hard coal (& non-renewable waste) 203 lignite 143 gas 467 of which from H2 0 oil 84 diesel 32 nuclear 45 biomass (& renewable waste) 8 hydro 175 wind 2 of which wind offshore 0 pv 1 geothermal 20 solar thermal power plants 0 ocean energy 0 combined heat and power plants 39 hard coal (& non-renewable waste) 28 lignite 5 gas 4 of which from H2 0 oil 2 biomass (& renewable waste) 0 geothermal 0 hydrogen 0 CHP by producer main activity producers 8 autoproducers 31 total generation 1,219 fossil 969 hard coal (& non-renewable waste) 231 lignite 147 gas 471 oil 87 diesel 32 nuclear 45 hydrogen 0 of which renewable H2 0 renewables (w/o renewable hydrogen) 206 hydro 175 wind 2 pv 1 biomass (& renewable waste) 8 geothermal 20 solar thermal power plants 0 ocean energy 0 distribution losses 99 own consumption electricity 54 electricity for hydrogen production 0 electricity for synfuel production 0 final energy consumption (electricity) 1,081 fluctuating res (pv, wind, ocean) 3 share of fluctuating res 0% res share (domestic generation) 17% table 13.9.9 Other asia: final energy consumption 2012 road 5,471 fossil fuels 5,143 biofuels 79 synfuels 0 natural gas 248 hydrogen 0 electricity 1 rail 65 fossil fuels 50 biofuels 0 synfuels 0 electricity 15 navigation 177 fossil fuels 177 biofuels 0 synfuels 0 aviation 172 fossil fuels 172 biofuels 0 synfuels 0 total (incl. pipelines) 5,886 fossil fuels 5,543 biofuels (incl. biogas) 79 synfuels 0 natural gas 248 hydrogen 0 electricity 15 total res 82 res share 1%

table 13.9.10: Other asia: installed capacity gw 2020 1,627 379 154 575 0 68 15 40 25 225 74 3 46 27 0 0 67 31 3 12 0 2 12 6 0

2025 1,907 344 67 594 0 54 10 35 25 240 228 77 143 114 48 5 112 29 2 38 0 2 28 14 0

2030 2,339 206 32 609 0 21 8 30 25 250 490 167 305 179 163 20 159 27 1 61 0 1 45 23 0

2040 3,698 32 4 554 11 4 1 12 30 270 1,136 351 694 364 488 110 231 10 0 106 5 0 75 39 0

2050 4,815 0 0 260 26 1 0 0 36 300 1,666 500 1,041 495 797 220 283 4 0 129 44 0 94 55 0

11 56 1,694 1,239 410 157 587 70 15 40 0 0 415 225 74 46 38 32 0 0 128 64 0 0 1,502 120 7% 25%

19 93 2,019 1,139 373 69 631 56 10 35 0 0 845 240 228 143 53 128 48 5 145 70 11 0 1,793 376 19% 42%

29 130 2,497 967 233 34 670 23 8 30 0 0 1,500 250 490 305 70 202 163 20 174 73 95 0 2,154 815 33% 60%

46 185 3,929 695 42 4 644 4 1 12 16 13 3,206 270 1,136 694 105 403 488 110 244 67 481 0 3,136 1,940 49% 82%

63 220 5,098 325 4 0 319 1 0 0 70 65 4,703 300 1,666 1,041 130 550 797 220 323 45 1,052 0 3,678 2,927 57% 94%

in transport pj/a 2020 2025 6,650 7,034 6,085 6,095 320 530 0 0 239 224 0 28 5 158 83 89 62 58 1 3 0 0 20 28 200 209 194 198 6 10 0 0 212 250 208 238 4 13 0 0 7,144 7,582 6,548 6,588 332 556 0 0 239 224 0 28 25 186 338 646 5% 9%

2030 7,202 5,554 686 0 216 244 501 108 61 5 0 43 235 206 28 0 264 245 18 0 7,808 6,067 738 0 216 244 544 1,211 16%

2040 7,129 3,105 825 0 185 1,141 1,873 136 37 16 0 83 213 181 32 0 345 293 52 0 7,824 3,616 925 0 185 1,141 1,956 3,463 44%

2050 5,398 649 665 0 119 1,843 2,122 160 14 12 0 134 221 122 100 0 499 274 224 0 6,278 1,059 1,000 0 119 1,843 2,256 4,835 77%

table 13.9.10 Other asia: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 105 105 0 0 0 10,247 5,167 4,215 4 0 0 861 0 10,352 5,272 4,215 4 0 0 861 0 42%

[r]evolution

2020 0 0 0 0 0 248 151 46 52 0 11,785 5,775 4,692 107 182 4 1,025 0 12,033 5,926 4,738 107 234 4 1,025 0 44%

2025 2 0 1 0 1 481 227 130 124 0 12,361 5,511 4,625 446 327 93 1,359 0 12,844 5,738 4,756 446 451 93 1,359 0 49%

2030 2 0 1 1 1 728 306 216 205 0 12,895 4,980 4,168 1,131 485 378 1,753 0 13,625 5,286 4,386 1,131 690 378 1,753 0 56%

2040 3 0 1 1 1 1,181 397 424 343 17 14,097 3,850 3,162 2,529 945 759 2,851 0 15,280 4,247 3,587 2,530 1,289 759 2,851 17 69%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2050 4 0 1 1 1 1,672 354 686 473 159 14,175 1,577 2,485 3,178 1,264 1,549 3,625 498 15,851 1,931 3,173 3,179 1,738 1,549 3,625 657 86%

2012 289 221 41 26 109 33 12 6 0 62 52 1 0 1 5 3 0 0 2 1% 21%

table 13.9.12: Other asia: final energy demand pj/a 2012 total (incl. non-energy use) 26,182 total energy use1 23,024 transport 5,886 oil products 5,543 natural gas 248 biofuels 79 synfuels 0 electricity 15 RES electricity 3 hydrogen 0 res share transport 1% industry 7,331 electricity 1,751 RES electricity 295 public district heat 9 RES district heat 0 hard coal & lignite 1,922 oil products 1,167 gas 1,433 solar 0 biomass 1,048 geothermal 0 hydrogen 0 res share industry 18% other sectors 9,807 electricity 2,125 RES electricity 358 public district heat 28 RES district heat 0 hard coal & lignite 183 oil products 1,328 gas 477 solar 4 biomass 5,663 geothermal 0 hydrogen 0 res share other sectors 61% total res 7,451 res share 32% non energy use 3,158 oil 2,489 gas 662 coal 7

2020 431 265 68 27 129 34 7 5 0 161 75 33 1 36 11 5 0 0 69 16% 37%

2020 30,298 27,120 7,144 6,548 239 332 0 25 6 0 5% 9,240 2,358 578 28 11 2,296 1,094 1,960 61 1,260 183 0 23% 10,736 3,023 741 38 15 94 1,013 688 46 5,833 1 0 62% 9,068 33% 3,178 2,296 680 202

2025 604 264 72 14 142 32 6 5 0 335 81 92 26 111 13 20 15 3 205 34% 56%

2025 31,679 28,356 7,582 6,588 224 556 0 186 78 28 9% 9,771 2,707 1,133 91 67 1,937 841 2,277 261 1,306 350 0 32% 11,003 3,560 1,490 45 33 12 844 807 185 5,508 42 0 66% 11,021 39% 3,323 2,268 711 345

2030 875 254 55 7 171 16 6 4 0 617 85 196 56 235 16 32 43 10 442 50% 71%

2030 32,479 29,050 7,808 6,067 216 738 0 544 327 244 16% 10,093 3,096 1,860 127 103 1,021 709 2,621 692 1,292 534 0 44% 11,149 4,115 2,472 74 60 22 772 811 438 4,695 221 0 71% 13,577 47% 3,429 2,203 734 493

2040 1,595 270 12 1 252 5 1 2 6 1,317 92 443 114 535 26 61 105 55 1,033 65% 83%

2040 33,882 30,240 7,824 3,616 185 925 0 1,956 1,603 1,141 44% 10,826 3,924 3,215 194 177 196 495 2,679 1,418 803 1,118 0 62% 11,590 5,411 4,433 124 114 0 429 622 1,112 3,509 384 0 82% 19,745 65% 3,643 2,048 779 815

2050 2,200 231 1 0 229 2 0 0 34 1,935 102 645 160 801 35 83 159 110 1,555 71% 88%

2050 32,860 28,841 6,278 1,059 119 1,000 0 2,256 2,111 1,843 77% 10,819 4,480 4,191 242 224 41 105 1,269 1,703 658 1,797 524 84% 11,744 6,504 6,084 188 174 0 18 390 1,475 2,541 628 0 93% 24,800 86% 4,019 1,939 860 1,221

1 excluding heat produced by chp autoproducers

table 13.9.13: Other asia: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (697 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 673 180 185 213 56 40 37 24 9 3 1 710 203 194 215 97

2020 831 336 167 256 54 18 43 29 6 7 1 874 365 173 263 73

2025 687 307 71 253 43 12 53 28 4 21 1 740 334 75 274 57

2030 495 185 33 250 17 10 63 27 3 33 1 559 212 36 283 28

2040 248 28 4 212 3 1 63 11 0 51 0 311 39 4 263 4

2050 91 0 0 91 1 0 47 5 0 41 0 138 5 0 132 1

733 582 1,741 250% 378 144 430 685 104 1,086 1.6

705 516 1,991 286% 449 123 505 841 73 1,193 1.7

649 366 1,801 258% 426 110 507 694 65 1,254 1.4

577 224 1,488 214% 357 105 467 502 56 1,308 1.1

447 79 895 128% 265 67 282 251 30 1,395 0.6

425 27 338 48% 126 23 86 95 8 1,449 0.2

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.9.14: Other asia: primary energy demand pj/a 2012 total 35,534 fossil 26,189 hard coal (& non-renewable waste) 4,127 lignite 2,157 natural gas 7,732 crude oil 12,173 nuclear 491 renewables 8,854 hydro 630 wind 6 solar 8 biomass (& renewable waste) 7,502 geothermal 708 ocean energy 0 of which non-energy use 3,158 net electricity imports (final energy) 55 total res incl. net electricity import 8,863 res share 25%

2020 41,007 29,825 6,145 2,151 9,036 12,493 436 10,745 809 266 275 8,356 1,040 0 3,178 0 10,745 26%

2025 43,369 28,212 5,639 1,151 9,641 11,780 382 14,776 864 821 1,135 8,517 3,421 18 3,323 0 14,776 34%

2030 44,188 25,073 3,657 658 10,251 10,507 327 18,787 900 1,765 2,815 8,038 5,197 72 3,429 0 18,787 43%

2040 46,795 18,149 1,477 37 9,806 6,829 131 28,515 972 4,091 6,785 6,785 9,485 396 3,643 0 28,515 61%

2050 45,676 9,754 1,320 0 5,256 3,178 0 35,922 1,080 5,999 9,794 5,929 12,328 792 4,019 0 35,922 79%

ot h e r a s i a : a d va n c e d e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.9.15 Other asia: electricity generation twh/a 2012 power plants 1,180 hard coal (& non-renewable waste) 203 lignite 143 gas 467 of which from H2 0 oil 84 diesel 32 nuclear 45 biomass (& renewable waste) 8 hydro 175 wind 2 of which wind offshore 0 pv 1 geothermal 20 solar thermal power plants 0 ocean energy 0 combined heat and power plants 39 hard coal (& non-renewable waste) 28 lignite 5 gas 4 of which from H2 0 oil 2 biomass (& renewable waste) 0 geothermal 0 hydrogen 0 CHP by producer main activity producers 8 autoproducers 31 total generation 1,219 fossil 969 hard coal (& non-renewable waste) 231 lignite 147 gas 471 oil 87 diesel 32 nuclear 45 hydrogen 0 of which renewable H2 0 renewables (w/o renewable hydrogen) 206 hydro 175 wind 2 pv 1 biomass (& renewable waste) 8 geothermal 20 solar thermal power plants 0 ocean energy 0 distribution losses 99 own consumption electricity 54 electricity for hydrogen production 0 electricity for synfuel production 0 final energy consumption (electricity) 1,081 fluctuating res (pv, wind, ocean) 3 share of fluctuating res 0% res share (domestic generation) 17%

table 13.9.18: Other asia: installed capacity gw 2020 1,629 364 154 590 0 68 15 40 25 225 74 3 46 27 1 0 67 31 3 12 0 2 12 6 0

2025 1,948 272 67 644 0 51 13 35 30 243 228 77 149 129 81 5 112 29 2 38 0 2 28 14 0

2030 2,465 108 32 639 0 18 11 30 30 253 505 182 376 209 234 20 159 27 1 61 0 1 45 23 0

2040 4,255 2 4 588 59 1 4 12 33 273 1,253 397 862 414 698 110 231 7 0 102 10 0 77 39 6

2050 6,298 0 0 305 305 0 0 0 28 300 1,988 600 1,338 564 1,556 220 283 0 0 90 90 0 107 56 31

11 56 1,696 1,240 396 157 602 70 15 40 0 0 416 225 74 46 38 32 1 0 128 64 0 0 1,503 120 7% 25%

19 93 2,060 1,118 302 69 681 53 13 35 0 0 907 243 228 149 58 143 81 5 145 70 17 0 1,828 382 19% 44%

29 130 2,624 899 135 34 700 20 11 30 0 0 1,695 253 505 376 75 232 234 20 174 73 127 0 2,250 901 34% 65%

46 185 4,485 639 9 4 621 1 4 12 75 64 3,760 273 1,253 862 110 453 698 110 244 67 836 15 3,322 2,226 50% 85%

63 220 6,581 0 0 0 0 0 0 0 425 425 6,156 300 1,988 1,338 135 620 1,556 220 323 45 2,136 69 4,008 3,546 54% 100%

table 13.9.16 Other asia: final energy consumption transport pj/a 2012 2020 2025 road 5,471 6,650 6,747 fossil fuels 5,143 6,085 5,774 biofuels 79 320 502 synfuels 0 0 0 natural gas 248 239 212 hydrogen 0 0 41 electricity 1 5 218 rail 65 83 157 fossil fuels 50 57 47 biofuels 0 1 5 synfuels 0 0 0 electricity 15 25 106 navigation 177 200 209 fossil fuels 177 198 206 biofuels 0 2 3 synfuels 0 0 0 aviation 172 212 245 fossil fuels 172 211 243 biofuels 0 1 2 synfuels 0 0 0 total (incl. pipelines) 5,886 7,144 7,358 fossil fuels 5,543 6,551 6,270 biofuels (incl. biogas) 79 324 512 synfuels 0 0 0 natural gas 248 239 212 hydrogen 0 0 41 electricity 15 30 323 total res 82 332 673 res share 1% 5% 9%

2030 6,676 4,969 614 0 195 323 575 237 42 7 0 187 235 212 22 0 256 233 23 0 7,403 5,456 667 0 195 323 762 1,368 18%

2040 6,080 2,022 730 18 129 1,322 1,878 408 19 12 0 377 213 139 73 2 321 209 110 3 7,040 2,388 925 23 129 1,322 2,254 3,992 57%

2050 4,078 0 431 48 0 1,750 1,897 559 0 12 1 546 221 0 199 22 399 0 359 40 5,305 0 1,000 112 0 1,750 2,443 5,305 100%

table 13.9.17 Other asia: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 0 0 0 0 0 105 105 0 0 0 10,247 5,167 4,215 4 0 0 861 0 10,352 5,272 4,215 4 0 0 861 0 42%

2020 1 0 1 0 0 248 150 45 52 0 11,785 5,775 4,692 107 182 4 1,025 0 12,033 5,926 4,738 107 234 4 1,025 0 44%

2025 2 0 1 0 1 481 227 130 124 0 12,361 5,520 4,625 446 327 93 1,350 0 12,844 5,747 4,756 446 451 93 1,350 0 49%

2030 2 0 1 1 1 728 306 216 205 0 12,895 4,994 4,168 1,131 485 378 1,740 0 13,625 5,300 4,386 1,131 690 378 1,740 0 57%

2040 2 0 1 1 1 1,193 348 431 345 69 14,084 3,491 3,226 2,527 944 759 2,849 290 15,280 3,839 3,658 2,528 1,289 759 2,849 358 72%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

350

2050 2 0 1 1 1 1,773 0 775 482 516 14,076 0 2,578 3,703 1,248 1,540 4,093 914 15,851 0 3,353 3,703 1,731 1,540 4,093 1,431 100%

2012 289 221 41 26 109 33 12 6 0 62 52 1 0 1 5 3 0 0 2 1% 21%

table 13.9.19: Other asia: final energy demand pj/a 2012 total (incl. non-energy use) 26,182 total energy use1 23,024 transport 5,886 oil products 5,543 natural gas 248 biofuels 79 synfuels 0 electricity 15 RES electricity 3 hydrogen 0 res share transport 1% industry 7,331 electricity 1,751 RES electricity 295 public district heat 9 RES district heat 0 hard coal & lignite 1,922 oil products 1,167 gas 1,433 solar 0 biomass 1,048 geothermal 0 hydrogen 0 res share industry 18% other sectors 9,807 electricity 2,125 RES electricity 358 public district heat 28 RES district heat 0 hard coal & lignite 183 oil products 1,328 gas 477 solar 4 biomass 5,663 geothermal 0 hydrogen 0 res share other sectors 61% total res 7,451 res share 32% non energy use 3,158 oil 2,489 gas 662 coal 7

2020 432 266 66 27 132 34 7 5 0 161 75 33 1 36 11 5 0 0 69 16% 37%

2020 30,298 27,120 7,144 6,551 239 324 0 30 7 0 5% 9,240 2,358 578 28 12 2,296 1,094 1,960 61 1,260 183 0 23% 10,736 3,023 741 38 16 94 1,013 688 46 5,833 1 0 62% 9,063 33% 3,178 2,296 680 202

2025 621 262 58 14 153 30 7 5 0 355 82 92 26 116 15 23 25 3 210 34% 57%

2025 31,457 28,133 7,358 6,270 212 512 0 323 142 41 9% 9,771 2,707 1,192 91 67 1,937 841 2,277 261 1,306 350 0 33% 11,004 3,551 1,564 45 33 23 844 807 185 5,508 42 0 67% 11,180 40% 3,323 2,268 711 345

2030 944 238 31 7 178 14 8 4 0 702 86 201 61 290 17 36 61 10 502 53% 74%

2030 32,176 28,747 7,403 5,456 195 667 0 762 492 323 18% 10,128 3,146 2,032 127 103 1,021 700 2,615 692 1,292 534 0 46% 11,216 4,191 2,707 74 60 38 758 801 438 4,695 221 0 72% 14,142 49% 3,429 2,203 734 493

2040 1,829 253 2 1 244 1 5 2 29 1,547 93 488 128 665 27 69 150 55 1,208 66% 85%

2040 33,377 29,734 7,040 2,388 129 925 23 2,254 1,921 1,322 57% 10,909 4,054 3,456 193 179 196 479 2,389 1,415 801 1,117 264 66% 11,785 5,651 4,817 124 115 0 402 464 1,112 3,599 384 49 85% 21,254 71% 3,643 1,880 779 983

2050 2,751 0 0 0 0 0 0 0 301 2,450 102 769 192 1,030 34 93 311 110 1,909 69% 89%

2050 32,132 28,112 5,305 0 0 1,000 112 2,443 2,443 1,750 100% 10,806 5,090 5,090 243 243 0 0 0 2,228 649 1,775 821 100% 12,001 6,896 6,896 188 188 0 0 0 1,475 2,673 628 141 100% 28,112 100% 4,019 1,552 860 1,608

1 excluding heat produced by chp autoproducers

table 13.9.20 Other asia: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (697 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 673 180 185 213 56 40 37 24 9 3 1 710 203 194 215 97

2020 825 324 167 263 54 18 43 29 6 7 1 868 352 173 270 73

2025 646 243 71 274 41 16 53 28 4 21 1 699 271 75 295 58

2030 421 97 33 263 15 14 63 27 3 33 1 484 123 36 296 29

2040 219 2 4 207 1 5 54 7 0 47 0 272 10 4 253 6

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

733 582 1,741 250% 378 144 430 685 104 1,086 1.6

700 512 1,986 285% 449 123 505 835 74 1,193 1.7

625 339 1,737 249% 426 111 482 653 66 1,254 1.4

538 184 1,359 195% 356 105 420 428 49 1,308 1.0

426 61 721 103% 239 56 186 221 18 1,395 0.5

0 0 0 0% 0 0 0 0 0 1,449 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.9.21: Other asia: primary energy demand pj/a 2012 total 35,534 fossil 26,189 hard coal (& non-renewable waste) 4,127 lignite 2,157 natural gas 7,732 crude oil 12,173 nuclear 491 renewables 8,854 hydro 630 wind 6 solar 8 biomass (& renewable waste) 7,502 geothermal 708 ocean energy 0 of which non-energy use 3,158 net electricity imports (final energy) 55 total res incl. net electricity import 8,863 res share 25%

2020 40,978 29,806 5,966 2,151 9,193 12,496 436 10,736 809 266 276 8,344 1,040 0 3,178 0 10,736 26%

2025 43,246 27,590 4,887 1,151 10,090 11,462 382 15,274 875 821 1,276 8,498 3,786 18 3,323 0 15,274 35%

2030 43,956 23,648 2,617 658 10,513 9,860 327 19,981 911 1,819 3,326 7,982 5,872 72 3,429 0 19,981 45%

2040 47,334 15,760 1,289 37 9,076 5,358 131 31,443 983 4,513 8,146 6,923 10,483 396 3,643 0 31,443 66%

2050 46,916 4,065 1,608 0 905 1,552 0 42,851 1,080 7,156 14,124 6,140 13,559 792 4,019 0 42,851 91%

energy

ot h e r a s i a : e m p loy m e n t r e s u lts table 13.9.22: Other asia: investments in electricity generation unit 201220212031ref 2020 2030 2040 fossil (w/o chp) billion $ 150.6 205.6 301.3 nuclear billion $ 14.3 8.3 0.0 chp (fossil + renewable) billion $ 8.5 6.5 5.2 renewables (w/o chp) billion $ 132.5 169.3 188.1 total billion $ 305.9 389.7 494.7 conventional (fossil & nuclear) billion $ 173.4 220.4 306.5 renewables billion $ 132.5 169.3 188.1 biomass billion $ 12.2 16.9 22.5 hydro billion $ 78.7 99.3 91.0 wind billion $ 5.5 18.6 32.9 pv billion $ 11.0 12.2 16.6 geothermal billion $ 25.1 21.7 24.6 solar thermal power plants billion $ 0.0 0.6 0.7 ocean energy billion $ 0.0 0.0 0.0 e[r] fossil (w/o chp) billion $ 104.9 56.3 91.1 nuclear billion $ 5.3 0.6 0.8 chp (fossil + renewable) billion $ 28.5 58.2 63.9 renewables (w/o chp) billion $ 226.6 1,078.5 1,482.1 total billion $ 365.3 1,193.6 1,637.8 conventional (fossil & nuclear) billion $ 119.0 71.7 104.6 renewables billion $ 246.3 1,121.8 1,533.2 biomass billion $ 16.3 21.4 38.6 hydro billion $ 82.9 38.1 34.7 wind billion $ 49.5 340.2 486.8 pv billion $ 62.5 261.0 343.0 geothermal billion $ 34.8 221.2 197.3 solar thermal power plants billion $ 0.3 190.7 269.1 ocean energy billion $ 0.0 49.3 163.6 adv e[r] fossil (w/o chp) billion $ 103.4 46.6 96.5 nuclear billion $ 5.3 0.6 0.8 chp (fossil + renewable) billion $ 28.5 58.2 64.0 renewables (w/o chp) billion $ 227.5 1,286.7 1,760.2 total billion $ 364.7 1,392.0 1,921.4 conventional (fossil & nuclear) billion $ 117.5 62.0 109.0 renewables billion $ 247.2 1,330.0 1,812.4 biomass billion $ 16.3 22.8 38.9 hydro billion $ 82.9 40.7 34.7 wind billion $ 49.5 356.5 558.2 pv billion $ 62.5 330.0 418.4 geothermal billion $ 34.8 257.5 214.7 solar thermal power plants billion $ 1.2 273.2 383.9 ocean energy billion $ 0.0 49.3 163.6

20412050 331.7 0.3 4.4 246.1 582.4 336.4 246.1 30.2 107.7 62.0 18.3 27.1 0.7 0.0

2012unit 2050 989.2 billion $/a 22.9 billion $/a 24.5 billion $/a 736.0 billion $/a 1,772.7 billion $/a 1,036.6 billion $/a 736.0 billion $/a 81.8 billion $/a 376.7 billion $/a 119.1 billion $/a 57.9 billion $/a 98.4 billion $/a 2.1 billion $/a 0.0 billion $/a

annual average

96.1 0.0 85.3 1,652.6 1,833.9 113.2 1,720.7 46.3 44.9 634.1 363.6 201.0 295.3 135.5

348.3 billion $/a 6.6 billion $/a 235.9 billion $/a 4,439.8 billion $/a 5,030.7 billion $/a 408.6 billion $/a 4,622.0 billion $/a 122.6 billion $/a 200.6 billion $/a 1,510.6 billion $/a 1,030.1 billion $/a 654.4 billion $/a 755.4 billion $/a 348.4 billion $/a

8.9 0.2 6.0 113.8 129.0 10.5 118.5 3.1 5.1 38.7 26.4 16.8 19.4 8.9

82.5 0.0 82.8 2,430.1 2,595.4 91.2 2,504.2 45.4 42.0 778.9 483.0 227.1 792.3 135.5

328.9 billion $/a 6.6 billion $/a 233.4 billion $/a 5,704.5 billion $/a 6,273.5 billion $/a 379.7 billion $/a 5,893.8 billion $/a 123.4 billion $/a 200.3 billion $/a 1,743.0 billion $/a 1,294.0 billion $/a 734.2 billion $/a 1,450.5 billion $/a 348.4 billion $/a

8.4 0.2 6.0 146.3 160.9 9.7 151.1 3.2 5.1 44.7 33.2 18.8 37.2 8.9

2012-2050 25.4 0.6 0.6 18.9 45.5 26.6 18.9 2.1 9.7 3.1 1.5 2.5 0.1 0.0

[r]evolution

table 13.9.23: Other asia: investments in renewable heat generation unit 2012202120312041ref 2020 2030 2040 2050 heat pumps billion $ 0.0 0.0 0.0 0.0 deep geothermal billion $ 0.0 0.0 0.0 0.0 solar thermal billion $ 3.1 2.0 5.0 4.6 biomass billion $ 52.6 35.3 24.8 14.1 total billion $ 55.7 37.3 29.8 18.8 e[r] heat pumps billion $ 0.9 108.8 91.0 253.2 deep geothermal billion $ 40.4 62.0 116.2 100.9 solar thermal billion $ 17.9 163.5 199.1 203.3 bomass billion $ 122.0 15.7 0.0 0.1 total billion $ 181.1 350.0 406.4 557.4 adv e[r] heat pumps billion $ 0.9 108.8 91.0 252.0 deep geothermal billion $ 40.5 62.0 115.9 98.2 solar thermal billion $ 17.9 163.5 198.6 305.6 biomass billion $ 122.0 15.7 0.0 0.0 total billion $ 181.3 349.9 405.5 655.7

table 13.9.24: Other asia: total employment in the energy sector

2012unit 2050 0.0 billion $/a 0.0 billion $/a 14.7 billion $/a 126.9 billion $/a 141.6 billion $/a

annual average

453.8 billion $/a 319.5 billion $/a 583.9 billion $/a 137.7 billion $/a 1494.9 billion $/a

11.6 8.2 15.0 3.5 38.3

452.6 billion $/a 316.6 billion $/a 685.6 billion $/a 137.6 billion $/a 1592.4 billion $/a

11.6 8.1 17.6 3.5 40.8

thousand jobs adv e [ r ] scenariO

reference scenariO

2012-2050 0.0 0.0 0.4 3.3 3.6

2015 644 297 349 1,812 71.3 36 3,209

2020 722 341 433 1,985 50.1 36 3,567

2025 646 312 484 1,980 22.4 32.5 3,476

2030 689 344 467 1,742 25.2 3,267

2020 903 376 547 2,021 52.3 363 4,262

2025 1,660 786 849 1,963 23.3 927 6,208

2030 1,500 845 1,105 1,568 1,511 6,528

783 811 38 1,578 1,266 203 13.3 47 12.4 0.2 36 0.0 3,209

870 963 37 1,697 1,305 249 32.7 62 11.4 0.8 36 3,567

816 1,019 31 1,610 1,210 249 43 63 9.9 1.0 32.5 3,476

946 964 28.1 1,329 985 199 56 55.1 7.9 1.0 25.2 3,267

126 950 20.0 3,166 1,391 150 412 699 78 37 35.4 243 120 4,262

90 987 19.8 5,112 1,321 118 823 1,472 92 299 60 773 154 6,208

45 905 16.7 5,562 1,032 99 886 1,483 90 306 153.7 1,207 305 6,528

351

china: reference scenario table 13.10.4: china: installed capacity gw

table 13.10.1 china: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share (domestic generation)

2012 3,671 2,526 0 41 0 8 0 97 34 863 96 1 6 0 0 0 1,353 1,270 0 83 0 0 0 0 0

2020 5,936 3,543 0 139 0 5 0 431 174 1,181 355 11 106 1 1 0 1,607 1,461 0 147 0 0 0 0 0

2025 7,253 4,344 0 213 0 4 0 607 220 1,257 470 30 133 2 2 0 1,704 1,514 0 190 0 0 0 0 0

2030 8,599 5,174 0 287 0 4 0 783 267 1,333 585 55 160 3 4 0 1,772 1,539 0 233 0 0 0 0 0

2040 10,634 6,572 0 444 0 4 0 908 321 1,423 733 107 200 8 20 2 1,862 1,543 0 319 0 0 0 0 0

2050 11,591 6,954 0 522 0 3 0 1,033 375 1,514 881 147 247 17 42 3 1,899 1,498 0 401 0 0 0 0 0

0 1,353 5,024 3,928 3,796 0 124 8 0 97 0 0 999 863 96 6 34 0 0 0 295 556 0 0 4,172 102 2% 20%

0 1,607 7,543 5,294 5,004 0 285 5 0 431 0 0 1,818 1,181 355 106 174 1 1 0 453 689 0 0 6,402 461 6% 24%

0 1,704 8,957 6,265 5,858 0 403 4 0 607 0 0 2,085 1,257 470 133 221 2 2 0 542 764 0 0 7,652 603 7% 23%

0 1,772 10,372 7,237 6,713 0 520 4 0 783 0 0 2,352 1,333 585 160 267 3 4 0 630 839 0 0 8,903 745 7% 23%

0 1,862 12,496 8,881 8,115 0 763 4 0 908 0 0 2,707 1,423 733 200 321 8 20 2 763 960 0 0 10,775 934 7% 22%

0 1,899 13,490 9,379 8,451 0 924 3 0 1,033 0 0 3,079 1,514 881 247 375 17 42 3 828 970 0 0 11,694 1,131 8% 23%

table 13.10.2 china: final energy consumption in transport pj/a 2012 2020 2025 road 8,149 12,096 15,204 fossil fuels 7,656 11,124 14,028 biofuels 51 135 255 synfuels 0 0 0 natural gas 443 819 839 hydrogen 0 0 0 electricity 0 19 82 rail 582 742 795 fossil fuels 395 395 395 biofuels 0 0 0 synfuels 0 0 0 electricity 187 347 400 navigation 806 935 1,019 fossil fuels 806 935 1,019 biofuels 0 0 0 synfuels 0 0 0 aviation 513 879 1,082 fossil fuels 513 879 1,082 biofuels 0 0 0 synfuels 0 0 0 total (incl. pipelines) 10,058 14,663 18,112 fossil fuels 9,370 13,332 16,524 biofuels (incl. biogas) 51 135 255 synfuels 0 0 0 natural gas 450 829 851 hydrogen 0 0 0 electricity 187 366 482 total res 88 223 367 res share 1% 2% 2%

2030 18,338 16,946 375 0 859 0 158 835 395 0 0 440 1,191 1,191 0 0 1,184 1,184 0 0 21,561 19,715 375 0 873 0 597 511 2%

2040 20,217 18,238 579 0 1,044 0 356 927 395 0 0 532 1,321 1,321 0 0 1,260 1,260 0 0 23,742 21,215 579 0 1,061 0 888 771 3%

2050 22,234 19,772 696 0 1,257 0 510 1,039 395 0 0 643 1,352 1,352 0 0 1,279 1,279 0 0 25,923 22,798 696 0 1,277 0 1,153 959 4%

table 13.10.3 china: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 3,413 3,402 12 0 0 3,077 3,077 0 0 0 32,424 23,433 6,209 539 0 256 1,987 0 38,915 29,912 6,221 539 0 256 1,987 0 19%

2020 4,366 4,334 32 0 0 3,852 3,852 0 0 0 37,248 28,441 5,383 821 0 379 2,225 0 45,467 36,626 5,416 821 0 379 2,225 0 16%

2025 4,547 4,504 43 0 0 4,225 4,225 0 0 0 38,366 29,541 5,087 928 0 454 2,356 0 47,138 38,269 5,131 928 0 454 2,356 0 15%

2030 4,730 4,676 54 0 0 4,552 4,552 0 0 0 39,492 30,656 4,777 1,036 0 527 2,496 0 48,773 39,883 4,832 1,036 0 527 2,496 0 15%

2040 4,656 4,584 72 0 0 5,153 5,152 1 0 0 39,606 30,476 4,466 1,114 0 746 2,803 0 49,414 40,212 4,539 1,114 0 746 2,803 0 14%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

352

2050 4,501 4,413 87 0 0 5,698 5,697 1 0 0 39,400 29,770 4,293 1,207 0 1,029 3,101 0 49,599 39,880 4,382 1,207 0 1,029 3,101 0 15%

2012 1,204 854 788 0 55 11 0 14 0 337 249 75 0 7 6 0 0 0 82 7% 28%

table 13.10.5: china: final energy demand pj/a 2012 total (incl. non-energy use) 71,629 total energy use1 65,916 transport 10,058 oil products 9,370 natural gas 450 biofuels 51 synfuels 0 electricity 187 RES electricity 37 hydrogen 0 res share transport 1% industry 33,988 electricity 10,071 RES electricity 2,003 public district heat 2,026 RES district heat 4 hard coal & lignite 14,919 oil products 2,452 gas 4,512 solar 0 biomass 0 geothermal 7 hydrogen 0 res share industry 6% other sectors 21,870 electricity 4,761 RES electricity 947 public district heat 937 RES district heat 2 hard coal & lignite 3,311 oil products 2,379 gas 1,487 solar 539 biomass 8,289 geothermal 166 hydrogen 0 res share other sectors 45% total res 12,045 res share 18% non energy use 5,714 oil 3,714 gas 577 coal 1,423

2020 1,858 1,145 1,035 0 100 10 0 58 0 655 360 183 4 81 30 0 0 0 265 14% 35%

2020 91,470 83,813 14,663 13,332 829 135 0 366 88 0 2% 43,843 14,936 3,600 2,603 19 18,167 2,688 5,367 9 62 11 0 8% 25,307 7,744 1,867 1,053 8 3,488 2,530 2,425 812 7,003 253 0 39% 13,867 17% 7,657 5,021 805 1,831

2025 2,163 1,330 1,191 0 130 10 0 82 0 751 383 227 10 103 38 0 1 0 329 15% 35%

2025 101,200 92,382 18,112 16,524 851 255 0 482 112 0 2% 46,986 17,531 4,081 2,726 26 17,176 2,729 6,540 18 254 14 0 9% 27,284 9,536 2,220 1,056 10 3,524 2,506 3,133 911 6,313 307 0 36% 14,519 16% 8,818 5,806 946 2,066

2030 2,467 1,515 1,346 0 160 9 0 105 0 847 406 269 18 124 46 0 1 0 393 16% 34%

2030 110,930 100,952 21,561 19,715 873 375 0 597 135 0 2% 50,129 20,127 4,564 2,849 33 16,728 2,769 7,170 26 445 16 0 10% 29,262 11,328 2,569 1,058 12 3,559 2,482 3,841 1,010 5,622 361 0 33% 15,168 15% 9,979 6,596 1,092 2,291

2040 2,863 1,779 1,563 0 208 7 0 122 0 962 434 312 33 155 55 1 5 1 468 16% 34%

2040 119,619 108,228 23,742 21,215 1,061 579 0 888 192 0 3% 52,957 23,963 5,191 2,816 43 15,045 2,531 7,762 84 732 23 0 11% 31,529 13,938 3,020 1,041 16 3,322 2,242 4,673 1,030 4,758 524 0 30% 16,193 15% 11,391 7,583 1,296 2,512

2050 3,011 1,785 1,539 0 239 7 0 139 0 1,087 461 362 44 186 64 2 10 1 550 18% 36%

2050 124,618 111,814 25,923 22,798 1,277 696 0 1,153 263 0 4% 53,865 26,360 6,016 2,725 53 13,445 2,272 7,725 194 1,112 31 0 14% 32,027 14,585 3,329 1,024 20 3,096 2,036 5,531 1,013 3,999 741 0 28% 17,467 16% 12,804 8,576 1,516 2,712

1 excluding heat produced by chp autoproducers

table 13.10.6: china: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (2,280 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 2,305 2,279 0 22 4 0 1,189 1,146 0 43 0 3,494 3,425 0 65 4

2020 3,429 3,355 0 67 7 0 1,449 1,383 0 66 0 4,877 4,737 0 133 7

2025 4,073 3,974 0 96 4 0 1,466 1,385 0 81 0 5,539 5,359 0 176 4

2030 4,733 4,609 0 122 2 0 1,467 1,371 0 96 0 6,200 5,980 0 218 2

2040 5,828 5,648 0 177 2 0 1,455 1,326 0 129 0 7,283 6,974 0 307 2

2050 5,942 5,746 0 194 2 0 1,450 1,287 0 162 0 7,392 7,033 0 357 2

890 695 8,229 361% 2,940 547 698 2,305 1,739 1,384 5.9

921 647 10,058 441% 3,553 624 1,004 3,429 1,449 1,440 7.0

884 618 10,993 482% 3,547 663 1,235 4,073 1,474 1,457 7.5

857 598 11,927 523% 3,545 703 1,466 4,733 1,480 1,461 8.2

820 583 12,938 567% 3,398 709 1,584 5,828 1,420 1,444 9.0

788 548 12,995 570% 3,229 720 1,709 5,942 1,394 1,393 9.3

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.10.7: china: primary energy demand pj/a 2012 total 114,448 fossil 100,346 hard coal (& non-renewable waste) 75,489 lignite 0 natural gas 5,143 crude oil 19,714 nuclear 1,063 renewables 13,039 hydro 3,107 wind 346 solar 562 biomass (& renewable waste) 8,846 geothermal 179 ocean energy 0 of which non-energy use 5,714 net electricity imports (final energy) -3 total res incl. net electricity import 13,038 res share 11%

2020 150,617 129,343 95,213 0 9,115 25,015 4,702 16,572 4,252 1,279 1,206 9,544 291 0 7,657 2 16,572 11%

2025 166,240 141,880 101,668 0 11,434 28,777 6,620 17,740 4,525 1,693 1,415 9,735 372 1 8,818 3 17,741 11%

2030 182,397 154,953 108,657 0 13,756 32,540 8,539 18,905 4,798 2,106 1,625 9,925 450 1 9,979 4 18,906 10%

2040 198,194 167,607 115,477 0 18,170 33,960 9,903 20,684 5,124 2,639 1,905 10,300 710 6 11,391 5 20,686 10%

2050 202,812 169,465 112,231 0 21,174 36,060 11,267 22,080 5,450 3,172 2,249 10,126 1,071 12 12,804 5 22,081 11%

energy

c h i n a : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.10.10: china: installed capacity gw

table 13.10.8 china: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share (domestic generation)

2012 3,671 2,526 0 41 0 8 0 97 34 863 96 1 6 0 0 0 1,353 1,270 0 83 0 0 0 0 0

2020 5,655 3,438 0 87 0 4 0 250 141 1,181 380 20 171 1 1 0 1,658 1,428 0 188 0 0 42 0 0

2025 6,107 3,348 0 91 0 3 0 230 150 1,220 679 82 348 3 32 2 1,909 1,346 0 344 0 0 200 19 0

2030 6,519 2,856 0 100 0 2 0 200 150 1,250 1,108 177 652 14 177 10 2,102 1,153 0 475 0 0 399 73 2

2040 7,765 1,753 0 92 0 0 0 146 151 1,310 2,128 467 1,293 49 783 60 2,235 545 0 683 7 0 671 303 34

2050 8,455 341 0 86 0 0 0 0 141 1,370 2,940 700 1,910 137 1,370 160 2,119 122 0 744 27 0 744 403 106

0 1,353 5,024 3,928 3,796 0 124 8 0 97 0 0 999 863 96 6 34 0 0 0 295 556 0 0 4,172 102 2% 20%

50 1,608 7,313 5,146 4,866 0 275 4 0 250 0 0 1,918 1,181 380 171 183 1 1 0 420 654 0 0 6,240 552 8% 26%

200 1,709 8,016 5,132 4,694 0 435 3 0 230 0 0 2,653 1,220 679 348 350 22 32 2 440 687 5 0 6,884 1,029 13% 33%

350 1,752 8,621 4,586 4,009 0 575 2 0 200 2 1 3,833 1,250 1,108 652 549 87 177 10 430 654 56 0 7,482 1,770 21% 44%

525 1,710 10,001 3,065 2,298 0 768 0 0 146 41 28 6,748 1,310 2,128 1,293 822 352 783 60 398 547 523 0 8,534 3,481 35% 68%

550 1,569 10,574 1,265 462 0 803 0 0 0 134 117 9,175 1,370 2,940 1,910 885 540 1,370 160 329 272 1,245 0 8,730 5,010 47% 88%

table 13.10.9 china: final energy consumption in transport pj/a 2012 2020 2025 road 8,149 11,524 12,819 fossil fuels 7,656 10,622 11,593 biofuels 51 142 243 synfuels 0 0 0 natural gas 443 724 731 hydrogen 0 0 13 electricity 0 36 238 rail 582 742 772 fossil fuels 395 385 332 biofuels 0 0 18 synfuels 0 0 0 electricity 187 357 422 navigation 806 930 1,000 fossil fuels 806 930 950 biofuels 0 0 50 synfuels 0 0 0 aviation 513 870 975 fossil fuels 513 870 948 biofuels 0 0 27 synfuels 0 0 0 total (incl. pipelines) 10,058 14,075 15,575 fossil fuels 9,370 12,807 13,823 biofuels (incl. biogas) 51 142 338 synfuels 0 0 0 natural gas 450 733 740 hydrogen 0 0 13 electricity 187 394 661 total res 88 245 561 res share 1% 2% 4%

2030 13,575 11,473 386 0 709 123 884 790 242 58 0 490 1,060 965 95 0 1,000 940 60 0 16,435 13,620 599 0 719 123 1,375 1,265 8%

2040 12,120 7,062 515 0 672 680 3,191 850 108 42 0 700 1,110 888 222 0 880 704 176 0 14,970 8,762 955 0 681 680 3,893 4,053 27%

2050 10,290 2,945 442 0 457 1,359 5,088 950 35 15 0 900 1,010 707 303 0 800 560 240 0 13,060 4,247 1,000 0 462 1,359 5,993 7,461 57%

table 13.10.10 china: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

[r]evolution

2012 3,413 3,402 12 0 0 3,077 3,077 0 0 0 32,424 23,433 6,209 539 0 256 1,987 0 38,915 29,912 6,221 539 0 256 1,987 0 19%

2020 3,922 3,834 68 20 0 4,655 4,485 170 0 0 35,575 25,620 5,766 922 0 555 2,711 0 44,152 33,939 6,005 942 0 555 2,711 0 19%

2025 3,916 3,244 280 313 78 5,793 4,804 821 168 0 34,993 23,490 5,887 1,400 73 1,070 3,073 0 44,702 31,537 6,989 1,713 319 1,070 3,073 0 25%

2030 3,755 2,728 427 413 188 7,028 4,739 1,641 635 13 32,742 19,577 5,380 2,303 141 1,939 3,402 0 43,525 27,043 7,448 2,716 964 1,939 3,402 13 34%

2040 3,334 975 581 1,000 777 9,356 3,721 2,766 2,602 266 25,769 8,997 4,601 4,427 251 3,506 3,733 254 38,459 13,692 7,949 5,427 3,631 3,506 3,733 520 62%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2050 2,806 112 505 1,066 1,122 10,043 2,676 3,055 3,447 864 21,272 2,709 4,865 4,793 292 4,046 3,962 605 34,121 5,498 8,425 5,859 4,862 4,046 3,962 1,469 82%

2012 1,204 854 788 0 55 11 0 14 0 337 249 75 0 7 6 0 0 0 82 7% 28%

table 13.10.12: china: final energy demand pj/a 2012 total (incl. non-energy use) 71,629 total energy use1 65,916 transport 10,058 oil products 9,370 natural gas 450 biofuels 51 synfuels 0 electricity 187 RES electricity 37 hydrogen 0 res share transport 1% industry 33,988 electricity 10,071 RES electricity 2,003 public district heat 2,026 RES district heat 7 hard coal & lignite 14,919 oil products 2,452 gas 4,512 solar 0 biomass 0 geothermal 7 hydrogen 0 res share industry 6% other sectors 21,870 electricity 4,761 RES electricity 947 public district heat 937 RES district heat 3 hard coal & lignite 3,311 oil products 2,379 gas 1,487 solar 539 biomass 8,289 geothermal 166 hydrogen 0 res share other sectors 45% total res 12,049 res share 18% non energy use 5,714 oil 3,714 gas 577 coal 1,423

2020 1,863 1,111 1,006 0 95 10 0 34 0 718 360 195 7 131 31 0 0 0 326 17% 39%

2025 2,163 1,101 954 0 140 7 0 31 0 1,031 372 320 27 266 60 3 9 1 587 27% 48%

2020 87,019 79,745 14,075 12,807 733 142 0 394 103 0 2% 41,097 14,657 3,843 2,450 112 15,915 2,376 5,161 98 321 119 0 11% 24,573 7,413 1,944 1,061 49 2,968 2,382 2,408 825 7,247 268 0 42% 15,071 19% 7,274 4,647 852 1,775

2025 89,449 81,865 15,575 13,823 740 338 0 661 219 13 4% 41,443 15,764 5,218 2,549 619 14,120 1,873 6,000 244 634 259 0 17% 24,847 8,358 2,767 1,459 354 1,977 1,886 2,475 1,156 6,966 571 0 48% 19,349 24% 7,583 4,671 986 1,926

2030 2,599 1,049 866 0 178 5 0 27 0 1,523 381 498 56 483 106 13 39 4 985 38% 59%

2040 3,382 786 566 0 219 0 0 20 11 2,565 399 884 144 892 164 53 154 21 1,796 53% 76%

2030 88,209 80,426 16,435 13,620 719 599 0 1,375 611 123 8% 39,710 16,563 7,366 2,590 998 11,265 914 6,289 691 738 660 0 26% 24,281 8,997 4,001 1,837 708 861 1,538 2,469 1,612 6,097 870 0 55% 25,005 31% 7,783 4,561 1,167 2,055

2040 78,033 70,287 14,970 8,762 681 955 0 3,893 2,638 680 27% 33,075 17,107 11,592 2,581 1,909 2,519 269 5,296 2,356 1,342 1,329 275 57% 22,241 9,723 6,588 2,322 1,717 0 398 1,918 2,071 4,317 1,494 0 73% 38,954 55% 7,746 4,075 1,472 2,200

2050 3,876 433 201 0 232 0 0 0 36 3,407 418 1,181 209 1,232 194 81 249 52 2,465 64% 88%

2050 68,393 60,967 13,060 4,247 462 1,000 0 5,993 5,267 1,359 57% 27,185 15,845 13,926 2,248 2,030 60 26 1,918 2,571 2,380 1,499 637 84% 20,722 9,588 8,427 2,456 2,218 0 46 1,171 2,222 3,411 1,827 0 87% 48,532 80% 7,426 3,535 1,634 2,257

1 excluding heat produced by chp autoproducers

table 13.10.13: china: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (2,280 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 2,305 2,279 0 22 4 0 1,189 1,146 0 43 0 3,494 3,425 0 65 4

2020 3,301 3,254 0 41 6 0 1,435 1,352 0 83 0 4,737 4,607 0 124 6

2025 3,105 3,063 0 39 3 0 1,375 1,231 0 144 0 4,480 4,294 0 183 3

2030 2,586 2,544 0 41 1 0 1,222 1,027 0 195 0 3,808 3,571 0 235 1

2040 1,542 1,507 0 35 0 0 741 468 0 273 0 2,283 1,975 0 309 0

2050 313 281 0 32 0 0 395 104 0 290 0 708 386 0 322 0

890 695 8,229 361% 2,940 547 698 2,305 1,739 1,384 5.9

921 648 9,475 416% 3,295 566 961 3,311 1,341 1,440 6.6

873 559 8,667 380% 3,058 445 1,035 3,140 989 1,457 5.9

830 442 7,351 322% 2,580 320 1,019 2,637 794 1,461 5.0

745 228 3,933 172% 1,214 132 667 1,598 322 1,444 2.7

560 67 1,319 58% 461 66 330 357 104 1,393 0.9

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.10.14: china: primary energy demand pj/a 2012 total 114,448 fossil 100,346 hard coal (& non-renewable waste) 75,489 lignite 0 natural gas 5,143 crude oil 19,714 nuclear 1,063 13,039 renewables hydro 3,107 wind 346 solar 562 biomass (& renewable waste) 8,846 geothermal 179 ocean energy 0 of which non-energy use 5,714 net electricity imports (final energy) -3 total res incl. net electricity import 13,038 res share 11%

2020 141,872 121,983 89,562 0 8,850 23,571 2,727 17,161 4,252 1,369 1,562 9,563 414 1 7,274 2 17,162 12%

2025 141,479 115,843 82,042 0 10,668 23,133 2,509 23,127 4,394 2,443 3,083 11,798 1,401 7 7,583 3 23,127 16%

2030 134,291 100,888 66,760 0 12,928 21,199 2,182 31,221 4,502 3,990 5,701 13,465 3,528 36 7,783 4 31,223 23%

2040 112,764 59,538 30,999 0 14,917 13,622 1,593 51,633 4,718 7,663 12,901 15,326 10,810 216 7,746 5 51,637 46%

2050 90,981 26,266 6,640 0 11,718 7,909 0 64,714 4,934 10,586 17,668 15,658 15,292 576 7,426 5 64,719 71%

c h i n a : a d va n c e d e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.10.18: china: installed capacity gw

table 13.10.15 china: electricity generation twh/a power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil diesel nuclear biomass (& renewable waste) hydro wind of which wind offshore pv geothermal solar thermal power plants ocean energy combined heat and power plants hard coal (& non-renewable waste) lignite gas of which from H2 oil biomass (& renewable waste) geothermal hydrogen CHP by producer main activity producers autoproducers total generation fossil hard coal (& non-renewable waste) lignite gas oil diesel nuclear hydrogen of which renewable H2 renewables (w/o renewable hydrogen) hydro wind pv biomass (& renewable waste) geothermal solar thermal power plants ocean energy distribution losses own consumption electricity electricity for hydrogen production electricity for synfuel production final energy consumption (electricity) fluctuating res (pv, wind, ocean) share of fluctuating res res share (domestic generation)

2012 3,671 2,526 0 41 0 8 0 97 34 863 96 1 6 0 0 0 1,353 1,270 0 83 0 0 0 0 0

2020 5,697 3,436 0 87 0 4 0 250 141 1,181 401 22 191 2 2 0 1,658 1,428 0 188 0 0 42 0 0

2025 6,260 3,319 0 91 0 3 0 230 150 1,220 760 113 421 9 52 4 1,909 1,346 0 344 2 0 200 19 0

2030 7,208 2,770 0 100 2 2 0 200 150 1,250 1,321 286 826 52 522 15 2,102 1,153 0 475 10 0 399 73 2

2040 9,765 792 0 97 14 0 0 146 151 1,310 3,032 951 1,752 220 2,185 80 2,235 545 0 683 96 0 671 303 34

2050 12,666 0 0 100 100 0 0 0 150 1,400 4,145 1,375 2,520 432 3,729 190 2,119 0 0 729 729 0 775 479 137

0 1,353 5,024 3,928 3,796 0 124 8 0 97 0 0 999 863 96 6 34 0 0 0 295 556 0 0 4,172 102 2% 20%

50 1,608 7,355 5,144 4,864 0 275 4 0 250 0 0 1,961 1,181 401 191 183 2 2 0 420 654 18 5 6,258 593 8% 27%

200 1,709 8,169 5,101 4,665 0 433 3 0 230 2 1 2,835 1,220 760 421 350 28 52 4 440 687 69 0 6,973 1,185 15% 35%

350 1,752 9,310 4,488 3,923 0 564 2 0 200 13 7 4,608 1,250 1,321 826 549 125 522 15 430 654 246 215 7,765 2,161 23% 50%

525 1,710 12,001 2,007 1,336 0 671 0 0 146 143 117 9,705 1,310 3,032 1,752 822 523 2,185 80 502 497 1,329 614 9,061 4,864 41% 82%

550 1,569 14,785 0 0 0 0 0 0 0 966 966 13,820 1,400 4,145 2,520 925 911 3,729 190 437 187 4,012 950 9,202 6,855 46% 100%

table 13.10.16 china: final energy consumption transport pj/a 2012 2020 2025 road 8,149 11,430 12,263 fossil fuels 7,656 10,475 10,882 biofuels 51 142 251 synfuels 0 7 0 natural gas 443 713 625 hydrogen 0 44 113 electricity 0 55 392 rail 582 759 885 fossil fuels 395 354 283 biofuels 0 0 15 synfuels 0 0 0 electricity 187 405 588 navigation 806 930 1,000 fossil fuels 806 930 990 biofuels 0 0 10 synfuels 0 0 0 aviation 513 861 946 fossil fuels 513 861 941 biofuels 0 0 5 synfuels 0 0 0 total (incl. pipelines) 10,058 13,996 15,103 fossil fuels 9,370 12,620 13,096 biofuels (incl. biogas) 51 142 281 synfuels 0 7 0 natural gas 450 722 634 hydrogen 0 44 113 electricity 187 460 980 total res 88 278 660 res share 1% 2% 4%

2030 12,043 9,572 404 207 466 360 1,241 1,049 191 22 11 824 1,030 891 92 47 930 809 80 41 15,269 11,463 599 306 475 360 2,066 1,953 13%

2040 8,440 2,859 631 595 112 1,361 3,477 1,522 54 19 17 1,432 1,000 650 180 170 695 452 125 118 12,262 4,015 955 900 119 1,361 4,913 6,826 56%

2050 5,892 0 426 608 0 1,383 4,083 2,105 0 10 15 2,080 850 0 350 500 520 0 214 306 9,985 0 1,000 1,429 0 1,383 6,173 9,985 100%

table 13.10.17 china: heat supply pj/a district heating plants fossil fuels biomass solar collectors geothermal heat from chp1 fossil fuels biomass geothermal hydrogen direct heating fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen total heat supply3 fossil fuels biomass solar collectors geothermal heat pumps2 electric direct heating hydrogen res share (including res electricity)

2012 3,413 3,402 12 0 0 3,077 3,077 0 0 0 32,424 23,433 6,209 539 0 256 1,987 0 38,915 29,912 6,221 539 0 256 1,987 0 19%

2020 3,922 3,834 68 20 0 4,655 4,485 170 0 0 35,575 25,620 5,766 922 0 555 2,711 0 44,152 33,939 6,005 942 0 555 2,711 0 19%

2025 3,916 3,244 280 313 78 5,793 4,799 821 168 5 34,993 23,453 5,887 1,400 73 1,070 3,073 37 44,702 31,495 6,989 1,713 319 1,070 3,073 42 25%

2030 3,755 2,728 427 413 188 7,028 4,711 1,641 635 41 32,742 19,423 5,380 2,303 141 1,939 3,402 153 43,525 26,862 7,448 2,716 964 1,939 3,402 194 35%

2040 3,334 975 581 1,000 777 9,356 3,450 2,766 2,602 537 25,769 8,204 4,601 4,427 251 3,632 3,733 921 38,459 12,629 7,949 5,427 3,631 3,632 3,733 1,458 65%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

354

2050 2,700 0 486 1,026 1,188 10,639 0 3,177 4,131 3,331 20,770 0 5,406 4,685 292 4,313 4,107 1,966 34,108 0 9,068 5,711 5,611 4,313 4,107 5,297 100%

2012 1,204 854 788 0 55 11 0 14 0 337 249 75 0 7 6 0 0 0 82 7% 28%

table 13.10.19: china: final energy demand pj/a 2012 total (incl. non-energy use) 71,629 total energy use1 65,916 transport 10,058 oil products 9,370 natural gas 450 biofuels 51 synfuels 0 electricity 187 RES electricity 37 hydrogen 0 res share transport 1% industry 33,988 electricity 10,071 RES electricity 2,003 public district heat 2,026 RES district heat 7 hard coal & lignite 14,919 oil products 2,452 gas 4,512 solar 0 biomass 0 geothermal 7 hydrogen 0 res share industry 6% other sectors 21,870 electricity 4,761 RES electricity 947 public district heat 937 RES district heat 3 hard coal & lignite 3,311 oil products 2,379 gas 1,487 solar 539 biomass 8,289 geothermal 166 hydrogen 0 res share other sectors 45% total res 12,049 res share 18% non energy use 5,714 oil 3,714 gas 577 coal 1,423

2020 1,889 1,111 1,006 0 95 10 0 34 0 744 360 205 7 146 31 0 1 0 352 19% 39%

2025 2,254 1,095 948 0 140 7 0 31 1 1,128 372 355 37 321 60 4 14 1 678 30% 50%

2020 86,940 79,666 13,996 12,620 722 142 7 460 123 44 2% 41,097 14,657 3,907 2,450 112 15,915 2,376 5,161 98 321 119 0 11% 24,573 7,413 1,976 1,061 49 2,968 2,382 2,408 825 7,247 268 0 42% 15,200 19% 7,274 4,647 852 1,775

2025 88,977 81,393 15,103 13,096 634 281 0 980 340 113 4% 41,443 15,764 5,473 2,549 619 14,120 1,873 5,970 244 634 259 30 17% 24,847 8,358 2,902 1,459 354 1,977 1,886 2,463 1,156 6,966 571 12 48% 19,853 24% 7,583 4,671 986 1,926

2030 2,876 1,026 847 0 175 5 0 27 4 1,819 381 582 91 612 106 19 114 5 1,199 42% 63%

2040 4,107 520 313 0 206 0 0 20 43 3,525 399 1,220 293 1,208 164 79 429 27 2,455 60% 86%

2030 87,280 79,497 15,269 11,463 475 599 306 2,066 1,024 360 13% 39,783 16,663 8,260 2,590 1,000 11,265 897 6,153 691 738 660 125 29% 24,446 9,225 4,573 1,837 709 861 1,500 2,397 1,612 6,097 870 47 57% 27,246 34% 7,783 4,561 1,167 2,055

2040 75,923 68,177 12,262 4,015 119 955 900 4,913 4,021 1,361 56% 33,283 17,395 14,236 2,581 1,928 2,519 238 4,754 2,356 1,342 1,329 769 66% 22,632 10,312 8,439 2,322 1,734 0 336 1,462 2,071 4,317 1,586 228 81% 46,980 69% 7,746 4,075 1,472 2,200

2050 5,074 0 0 0 0 0 0 0 338 4,736 427 1,604 402 1,626 203 137 678 62 3,291 65% 93%

2050 65,692 58,266 9,985 0 0 1,000 1,429 6,173 6,173 1,383 100% 26,926 16,442 16,442 2,154 2,154 0 0 0 2,463 2,607 1,437 1,823 100% 21,355 10,511 10,511 2,456 2,456 0 0 0 2,222 3,829 2,091 246 100% 58,266 100% 7,426 3,535 1,634 2,257

1 excluding heat produced by chp autoproducers

table 13.10.20 china: cO2 emissions mill t/a condensation power plants hard coal (& non-renewable waste) lignite gas oil diesel combined heat and power plants hard coal (& non-renewable waste) lignite gas oil co2 emissions power and chp plants hard coal (& non-renewable waste) lignite gas oil & diesel co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation co2 intensity total electr. generation co2 emissions by sector % of 1990 emissions (2,280 mill t) industry1 other sectors1 transport power generation2 other conversion3 population (mill.) co2 emissions per capita (t/capita)

2012 2,305 2,279 0 22 4 0 1,189 1,146 0 43 0 3,494 3,425 0 65 4

2020 3,300 3,253 0 41 6 0 1,435 1,352 0 83 0 4,735 4,605 0 124 6

2025 3,078 3,036 0 39 3 0 1,375 1,231 0 143 0 4,452 4,267 0 182 3

2030 2,509 2,467 0 40 1 0 1,218 1,027 0 191 0 3,726 3,495 0 231 1

2040 713 681 0 32 0 0 706 468 0 238 0 1,418 1,149 0 270 0

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

890 695 8,229 361% 2,940 547 698 2,305 1,739 1,384 5.9

921 644 9,421 413% 3,295 566 947 3,310 1,303 1,440 6.5

873 545 8,526 374% 3,056 445 976 3,113 936 1,457 5.9

830 400 6,969 306% 2,569 314 850 2,559 677 1,461 4.8

707 118 2,521 111% 1,152 103 295 763 207 1,444 1.7

0 0 0 0% 0 0 0 0 0 1,393 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.10.21: china: primary energy demand pj/a 2012 total 114,448 fossil 100,346 hard coal (& non-renewable waste) 75,489 lignite 0 natural gas 5,143 crude oil 19,714 nuclear 1,063 13,039 renewables hydro 3,107 wind 346 solar 562 biomass (& renewable waste) 8,846 geothermal 179 ocean energy 0 of which non-energy use 5,714 net electricity imports (final energy) -3 total res incl. net electricity import 13,038 res share 11%

2020 140,244 120,207 87,051 0 9,783 23,373 2,727 17,310 4,252 1,446 1,638 9,532 442 1 7,274 2 17,311 12%

2025 138,209 111,915 77,607 0 11,939 22,370 2,509 23,784 4,394 2,737 3,416 11,676 1,547 14 7,583 3 23,785 17%

2030 130,456 93,571 60,386 0 14,273 18,912 2,182 34,703 4,502 4,756 7,568 13,432 4,391 54 7,783 4 34,705 27%

2040 107,973 41,233 19,033 0 13,479 8,721 1,593 65,148 4,718 10,919 19,602 15,296 14,326 288 7,746 5 65,153 60%

2050 95,275 7,487 2,258 0 1,695 3,535 0 87,787 5,041 14,924 28,211 16,629 22,299 684 7,426 5 87,793 92%

energy

c h i n a : i n v e st m e n t a n d e m p loy m e n t table 13.10.22: china: investments in electricity unit 2012ref 2020 fossil (w/o chp) billion $ 327.4 nuclear billion $ 134.4 chp (fossil + renewable) billion $ 132.4 renewables (w/o chp) billion $ 651.9 total billion $ 1,246.1 conventional (fossil & nuclear) billion $ 594.1 renewables billion $ 652.0 biomass billion $ 40.1 hydro billion $ 290.7 wind billion $ 174.0 pv billion $ 145.5 geothermal billion $ 0.7 solar thermal power plants billion $ 1.0 ocean energy billion $ 0.0 e[r] fossil (w/o chp) billion $ 293.7 nuclear billion $ 59.0 chp (fossil + renewable) billion $ 149.3 renewables (w/o chp) billion $ 750.6 total billion $ 1,252.6 conventional (fossil & nuclear) billion $ 486.8 renewables billion $ 765.8 biomass billion $ 46.3 hydro billion $ 290.7 wind billion $ 195.4 pv billion $ 231.4 geothermal billion $ 0.7 solar thermal power plants billion $ 1.1 ocean energy billion $ 0.1 adv e[r] fossil (w/o chp) billion $ 293.4 nuclear billion $ 59.0 chp (fossil + renewable) billion $ 149.3 renewables (w/o chp) billion $ 795.2 total billion $ 1,296.9 conventional (fossil & nuclear) billion $ 486.4 renewables billion $ 810.5 biomass billion $ 46.3 hydro billion $ 290.7 wind billion $ 210.5 pv billion $ 257.7 geothermal billion $ 2.6 solar thermal power plants billion $ 2.5 ocean energy billion $ 0.1

generation 202120312030 2040 578.5 579.6 172.0 69.5 278.7 210.5 401.4 553.1 1,430.6 1,412.8 1,029.2 859.6 401.4 553.1 30.8 54.1 129.1 93.8 177.0 268.4 58.3 113.5 2.7 4.2 3.5 17.3 0.0 1.8

20412050 668.4 81.1 26.2 470.3 1,246.0 775.7 470.3 43.7 95.2 241.1 58.7 7.4 23.0 1.2

2012unit 2050 2,153.9 billion $/a 457.0 billion $/a 647.8 billion $/a 2,076.7 billion $/a 5,335.5 billion $/a 3,258.6 billion $/a 2,076.8 billion $/a 168.7 billion $/a 608.8 billion $/a 860.5 billion $/a 375.9 billion $/a 14.9 billion $/a 44.9 billion $/a 3.1 billion $/a

annual average

25.4 0.0 442.6 1,293.0 1,761.0 228.8 1,532.1 157.1 79.4 519.6 462.4 123.1 173.5 17.1

12.1 0.0 541.5 2,095.6 2,649.3 151.1 2,498.2 169.7 75.1 827.0 550.5 307.6 508.1 60.2

209.6 0.0 470.0 2,181.7 2,861.3 272.2 2,589.0 263.9 76.2 929.2 543.6 248.4 450.4 77.4

540.8 billion $/a 59.0 billion $/a 1,603.4 billion $/a 6,320.9 billion $/a 8,524.1 billion $/a 1,139.0 billion $/a 7,385.2 billion $/a 637.0 billion $/a 521.4 billion $/a 2,471.2 billion $/a 1,787.9 billion $/a 679.8 billion $/a 1,133.1 billion $/a 154.8 billion $/a

13.9 1.5 41.1 162.1 218.6 29.2 189.4 16.3 13.4 63.4 45.8 17.4 29.1 4.0

16.1 0.0 442.6 1,987.3 2,446.0 219.6 2,226.4 157.1 79.4 676.9 610.4 164.5 511.9 26.2

20.9 0.0 541.5 3,827.7 4,390.1 159.9 4,230.2 169.7 75.1 1,338.7 758.4 419.6 1,390.9 77.9

348.2 678.6 billion $/a 0.0 59.0 billion $/a 555.5 1,688.8 billion $/a 3,451.5 10,061.7 billion $/a 4,355.1 12,488.1 billion $/a 408.1 1,274.0 billion $/a 3,947.0 11,214.2 billion $/a 279.0 652.1 billion $/a 94.6 539.9 billion $/a 1,228.9 3,455.0 billion $/a 694.4 2,321.0 billion $/a 423.6 1,010.2 billion $/a 1,141.5 3,046.8 billion $/a 85.0 189.2 billion $/a

17.4 1.5 43.3 258.0 320.2 32.7 287.5 16.7 13.8 88.6 59.5 25.9 78.1 4.9

2012-2050 55.2 11.7 16.6 53.2 136.8 83.6 53.3 4.3 15.6 22.1 9.6 0.4 1.2 0.1

[r]evolution

table 13.10.23: china: investments in renewable unit 2012ref 2020 heat pumps billion $ 77.7 deep geothermal billion $ 0.0 solar thermal billion $ 22.4 biomass billion $ 5.8 total billion $ 105.9 e[r] heat pumps billion $ 111.2 deep geothermal billion $ 0.0 solar thermal billion $ 51.3 bomass billion $ 23.5 total billion $ 186.1 adv e[r] heat pumps billion $ 111.2 deep geothermal billion $ 0.0 solar thermal billion $ 51.3 biomass billion $ 23.5 total billion $ 186.1

heat generation 202120312030 2040 80.7 111.4 0.0 0.0 19.3 34.8 22.5 20.1 122.4 166.3

20412050 121.0 0.0 30.2 37.9 189.0

2012unit 2050 390.7 billion $/a 0.0 billion $/a 106.7 billion $/a 86.2 billion $/a 583.6 billion $/a

annual average

357.7 68.1 238.1 50.5 714.3

416.9 364.8 527.1 58.8 1,367.7

414.4 314.0 248.6 69.4 1,046.4

1,300.1 billion $/a 746.9 billion $/a 1,065.1 billion $/a 202.3 billion $/a 3,314.4 billion $/a

33.3 19.2 27.3 5.2 85.0

357.7 68.1 238.1 50.5 714.3

454.3 364.8 527.1 58.8 1,405.1

467.9 346.1 144.1 80.5 1,038.6

1,391.1 billion $/a 779.0 billion $/a 960.6 billion $/a 213.4 billion $/a 3,344.1 billion $/a

35.7 20.0 24.6 5.5 85.7

table 13.10.24: china: total employment in the energy sector

thousand jobs adv e [ r ] scenariO

reference scenariO

2012-2050 10.0 0.0 2.7 2.2 15.0

2015 1,544 808 720 4,167 205 7,443

2020 1,328 667 998 3,730 233 6,956

2025 1,197 619 1,075 3,219 138 6,248

2030 776 403 1,039 2,773 129 5,121

2020 931 918 1,059 3,616 410 6,934

2025 1,499 1,303 1,373 2,929 884 7,987

2030 1,441 1,353 1,653 2,314 1,264 8,025

4,985 316 178 1,964 709 422 298 326 1.2 2.0 0.01 155 50.2 7,443

4,462 501 253 1,739 738 263 280 221 1.2 2.9 0.17 192 40.2 6,956

3,832 632 223 1,560 694 249 281 195 1.1 3.3 0.30 107 31.2 6,248

3,029 747 170 1,175 549 173 189 126 1.0 6.2 0.75 104 25.8 5,121

2,950 549 53 3,382 860 213 789 1,054 8 35 12.3 317 93 6,934

2,016 695 46 5,230 1,256 187 1,109 1,496 37 233 28.3 625 258 7,987

1,238 852 32 5,903 1,265 150 1,316 1,309 60 499 40.1 968 296 8,025

355

oecd asia oceania: reference scenario table 13.11.1 Oecd asia Oceania: electricity generation twh/a 2012 2020 1,780 1,944 515 567 144 145 570 406 0 0 194 54 7 7 166 446 35 52 116 133 14 46 0 1 10 68 9 16 0 1 0 2 69 117 7 15 2 0 53 87 0 0 5 9 2 5 0 0 0 1

33 36 1,849 1,497 521 146 623 200 7 166 0 0 186 116 14 10 37 9 0 0 78 119 0 0 1,652 23 1% 10%

45 72 2,061 1,289 581 145 493 63 7 446 1 0 325 133 46 68 58 16 1 2 87 133 3 0 1,837 116 6% 16%

2025 2,031 567 145 434 0 37 7 471 60 137 69 2 76 25 3 2 133 17 0 100 0 9 7 0 1

2030 2,122 568 145 466 0 19 7 496 67 141 91 4 83 33 4 3 146 19 0 109 0 10 8 0 1

2040 2,258 573 140 487 0 16 7 517 79 149 135 11 94 49 7 6 172 23 0 129 0 8 10 0 1

2050 2,281 547 130 472 0 12 6 517 94 149 158 19 106 69 11 10 204 26 0 157 0 7 13 0 1

50 83 2,164 1,316 584 145 534 46 7 471 1 0 377 137 69 76 66 25 3 2 91 137 3 0 1,931 147 7% 17%

50 96 2,268 1,342 587 145 575 29 7 496 1 0 429 141 91 83 75 33 4 3 96 142 4 0 2,025 177 8% 19%

56 116 2,430 1,383 597 140 616 24 7 517 1 0 529 149 135 94 89 49 7 6 103 148 4 0 2,174 234 10% 22%

69 135 2,485 1,357 573 130 629 20 6 517 1 0 610 149 158 106 106 69 11 10 105 148 4 0 2,227 275 11% 25%

table 13.11.2 Oecd asia Oceania: final energy consumption in transport pj/a 2012 2020 2025 2030 road 5,244 4,976 4,757 4,538 fossil fuels 5,167 4,858 4,610 4,361 biofuels 27 28 29 29 synfuels 0 0 0 0 natural gas 51 73 88 103 hydrogen 0 0 0 0 electricity 0 17 31 45 rail 149 151 152 152 fossil fuels 59 60 60 60 biofuels 0 0 0 0 synfuels 0 0 0 0 electricity 90 91 92 92 navigation 180 170 165 160 fossil fuels 180 170 165 160 biofuels 0 0 0 0 synfuels 0 0 0 0 aviation 292 308 317 325 fossil fuels 292 308 317 325 biofuels 0 0 0 0 synfuels 0 0 0 0 total (incl. pipelines) 5,881 5,621 5,405 5,190 fossil fuels 5,698 5,397 5,151 4,906 biofuels (incl. biogas) 27 28 29 29 synfuels 0 0 0 0 natural gas 67 88 103 118 hydrogen 0 0 0 0 electricity 90 108 122 137 total res 36 45 50 55 res share 1% 1% 1% 1% table 13.11.3 Oecd asia Oceania: heat supply pj/a 2012 153 140 12 0 0 172 165 7 1 0 7,249 6,234 249 27 0 30 708 0 7,573 6,540 268 27 1 30 708 0 5%

2020 146 119 27 0 0 310 286 20 0 4 7,387 6,237 377 46 0 31 695 0 7,842 6,643 423 46 0 31 695 4 8%

2025 142 116 26 0 0 365 336 25 0 5 7,454 6,254 409 64 0 33 695 0 7,961 6,706 460 64 0 33 695 5 9%

2040 4,332 4,076 32 0 148 0 76 153 60 0 0 93 150 150 0 0 342 342 0 0 4,992 4,628 32 0 163 0 169 68 1%

2030 152 124 28 0 0 421 384 32 0 5 7,541 6,290 441 81 0 34 695 0 8,114 6,799 501 81 0 34 695 5 9%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

356

2040 144 118 26 0 0 562 506 50 0 6 7,657 6,282 513 131 0 36 695 0 8,363 6,906 589 131 0 36 695 6 11%

2050 3,755 3,412 28 0 203 0 113 154 60 0 0 94 140 140 0 0 338 338 0 0 4,403 3,949 28 0 219 0 207 78 2%

2050 170 139 31 0 0 783 689 87 0 6 7,829 6,263 615 199 0 38 714 0 8,782 7,091 733 199 0 38 714 6 13%

table 13.11.4: Oecd asia Oceania: installed capacity gw 2012 total generation 458 fossil 297 hard coal (& non-renewable waste) 77 lignite 21 gas (w/o h2) 140 oil 57 diesel 2 nuclear 68 hydrogen (fuel cells, gas power plants, gas chp) 0 renewables 93 hydro 69 wind 6 of which wind offshore 0 pv 10 biomass (& renewable waste) 6 geothermal 1 solar thermal power plants 0 ocean energy 0 fluctuating res (pv, wind, ocean) 16 share of fluctuating res 4% res share (domestic generation) 20%

2020 549 323 95 24 172 29 3 67 0 159 71 16 0 59 10 2 0 1 76 14% 29%

table 13.11.5: Oecd asia Oceania: final energy demand pj/a 2012 2020 total (incl. non-energy use) 23,756 24,178 total energy use1 20,108 20,583 transport 5,881 5,621 oil products 5,698 5,397 natural gas 67 88 biofuels 27 28 synfuels 0 0 electricity 90 108 RES electricity 9 17 hydrogen 0 0 res share transport 1% 1% industry 6,564 6,960 electricity 2,235 2,520 RES electricity 225 398 public district heat 89 85 RES district heat 3 11 hard coal & lignite 1,161 1,521 oil products 1,231 1,243 gas 1,590 1,181 solar 0 2 biomass 252 401 geothermal 7 7 hydrogen 0 0 res share industry 7% 12% other sectors 7,663 8,002 electricity 3,624 3,987 RES electricity 364 629 public district heat 142 168 RES district heat 4 22 hard coal & lignite 81 56 oil products 1,886 1,751 gas 1,810 1,881 solar 27 44 biomass 80 101 geothermal 13 15 hydrogen 0 0 res share other sectors 6% 10% total res 1,011 1,674 res share 5% 8% non energy use 3,647 3,595 oil 3,542 3,484 gas 71 79 coal 34 32

2025 574 331 98 24 182 23 4 66 0 177 72 24 1 65 11 4 1 1 89 16% 31%

2025 24,225 20,680 5,405 5,151 103 29 0 122 21 0 1% 6,991 2,606 454 86 11 1,437 1,170 1,251 3 432 7 0 13% 8,284 4,224 736 176 22 52 1,635 2,007 60 113 16 0 11% 1,904 9% 3,545 3,428 85 32

2030 599 339 101 25 191 18 4 65 0 194 74 31 1 71 12 5 1 1 102 17% 32%

2030 24,272 20,798 5,190 4,906 118 29 0 137 26 0 1% 7,022 2,691 509 86 11 1,352 1,098 1,322 5 462 7 0 14% 8,586 4,462 844 184 24 49 1,539 2,133 77 126 17 0 13% 2,137 10% 3,475 3,353 90 31

2040 631 338 103 24 191 16 4 68 0 225 76 44 3 79 15 7 2 2 125 20% 36%

2050 651 333 99 22 195 13 4 68 0 250 76 51 5 89 18 10 2 3 144 22% 38%

2040 24,143 21,007 4,992 4,628 163 32 0 169 37 0 1% 6,888 2,779 605 78 10 1,172 953 1,387 7 505 7 0 16% 9,127 4,877 1,061 200 26 45 1,329 2,384 125 149 19 0 15% 2,582 12% 3,136 3,014 94 28

2050 23,393 20,596 4,403 3,949 219 28 0 207 51 0 2% 6,755 2,869 704 70 9 960 820 1,463 9 557 7 0 19% 9,439 4,940 1,213 261 35 41 1,142 2,669 190 175 21 0 17% 2,999 15% 2,797 2,702 95 0

1 excluding heat produced by chp autoproducers

table 13.11.6: Oecd asia Oceania: cO2 emissions mill t/a 2012 condensation power plants 998 hard coal (& non-renewable waste) 440 lignite 171 gas 254 oil 127 diesel 5 combined heat and power plants 45 hard coal (& non-renewable waste) 9 lignite 3 gas 27 oil 6 co2 emissions power and chp plants 1,043 hard coal (& non-renewable waste) 450 lignite 174 gas 281 oil & diesel 138 co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation 697 co2 intensity total electr. generation 564 co2 emissions by sector 2,214 % of 1990 emissions (1,566 mill t) 141% industry1 319 other sectors1 258 transport 439 power generation2 1,016 other conversion3 181 population (mill.) 204 co2 emissions per capita (t/capita) 10.9

2020 844 463 160 176 39 6 71 20 0 44 7 915 483 160 220 51

2025 824 461 156 175 27 5 80 23 0 50 7 904 483 157 225 39

2030 811 454 153 183 15 5 87 26 0 54 7 897 480 153 237 27

2040 799 451 144 186 13 5 100 30 0 64 5 898 481 145 250 23

2050 750 434 134 167 9 5 114 32 0 77 5 864 467 134 245 19

709 444 2,020 129% 350 250 417 869 134 206 9.8

687 418 1,960 125% 345 250 399 852 114 207 9.5

668 396 1,908 122% 341 252 381 837 96 206 9.2

650 370 1,847 118% 323 254 363 828 79 203 9.1

637 348 1,734 111% 299 262 314 785 75 199 8.7

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.11.7: Oecd asia Oceania: primary energy demand pj/a 2012 2020 total 35,801 36,767 fossil 32,365 29,291 hard coal (& non-renewable waste) 8,092 8,420 lignite 1,592 1,469 natural gas 7,667 6,103 crude oil 15,014 13,299 nuclear 1,814 4,862 renewables 1,622 2,614 hydro 419 480 wind 50 165 solar 62 298 biomass (& renewable waste) 826 1,183 geothermal 266 482 ocean energy 0 6 of which non-energy use 3,647 3,595 net electricity imports (final energy) 0 -3 total res incl. net electricity import 1,622 2,613 res share 5% 7%

2025 36,909 28,746 8,324 1,434 6,422 12,567 5,136 3,027 493 247 345 1,310 624 8 3,545 -3 3,027 8%

2030 37,175 28,317 8,189 1,400 6,894 11,834 5,409 3,449 506 328 393 1,444 767 11 3,475 -4 3,448 9%

2040 37,293 27,446 7,997 1,322 7,509 10,618 5,641 4,205 537 485 495 1,667 1,001 20 3,136 -5 4,204 11%

2050 36,412 25,810 7,535 1,227 7,848 9,200 5,641 4,961 537 570 620 1,923 1,275 36 2,797 -5 4,960 14%

energy

a s i a o c e a n i a : e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.11.8 Oecd asia Oceania: electricity generation twh/a 2012 2020 power plants 1,780 1,883 hard coal (& non-renewable waste) 515 492 lignite 144 110 gas 570 462 of which from H2 0 0 oil 194 120 diesel 7 3 nuclear 166 163 biomass (& renewable waste) 35 74 hydro 116 150 wind 14 130 of which wind offshore 0 25 pv 10 98 geothermal 9 56 solar thermal power plants 0 16 ocean energy 0 9 combined heat and power plants 69 100 hard coal (& non-renewable waste) 7 8 lignite 2 5 gas 53 68 of which from H2 0 0 oil 5 4 biomass (& renewable waste) 2 11 geothermal 0 4 hydrogen 0 1 CHP by producer main activity producers 33 42 autoproducers 36 58 total generation 1,849 1,983 fossil 1,497 1,272 hard coal (& non-renewable waste) 521 500 lignite 146 115 gas 623 530 oil 200 124 diesel 7 3 nuclear 166 163 hydrogen 0 1 of which renewable H2 0 0 renewables (w/o renewable hydrogen) 186 548 hydro 116 150 wind 14 130 pv 10 98 biomass (& renewable waste) 37 85 geothermal 9 60 solar thermal power plants 0 16 ocean energy 0 9 distribution losses 78 83 own consumption electricity 119 112 electricity for hydrogen production 0 3 electricity for synfuel production 0 0 final energy consumption (electricity) 1,652 1,786 fluctuating res (pv, wind, ocean) 23 237 share of fluctuating res 1% 12% res share (domestic generation) 10% 28%

2025 1,897 469 92 403 0 72 3 50 71 155 230 50 210 72 40 30 140 10 3 87 0 3 27 8 1

2030 1,959 313 50 390 0 29 3 0 73 159 390 110 310 99 100 45 166 9 0 90 0 4 50 11 2

2040 2,077 20 5 337 17 13 1 0 60 163 680 230 440 135 140 85 208 3 0 73 0 2 100 25 4

2050 1,943 0 0 69 28 5 0 0 37 180 732 262 469 146 175 130 245 0 0 36 5 0 148 54 8

60 80 2,036 1,143 480 95 490 75 3 50 1 0 843 155 230 210 98 80 40 30 85 100 8 0 1,843 470 23% 41%

68 98 2,125 887 322 50 480 33 3 0 2 1 1,237 159 390 310 123 110 100 45 87 90 52 0 1,896 745 35% 58%

88 120 2,285 436 23 5 393 15 1 0 21 17 1,828 163 680 440 160 160 140 85 90 73 198 0 1,924 1,205 53% 81%

110 135 2,188 78 0 0 73 5 0 0 40 38 2,070 180 732 469 184 200 175 130 90 59 317 0 1,722 1,331 61% 96%

table 13.11.9 Oecd asia Oceania: final energy consumption in transport pj/a 2012 2020 2025 2030 road 5,244 5,037 4,450 3,784 5,167 4,778 3,830 2,782 fossil fuels biofuels 27 148 333 379 synfuels 0 0 0 0 natural gas 51 90 103 107 hydrogen 0 1 12 114 electricity 0 20 173 402 rail 149 144 135 132 fossil fuels 59 45 30 20 biofuels 0 3 4 4 synfuels 0 0 0 0 electricity 90 96 102 108 navigation 180 173 162 151 fossil fuels 180 168 154 133 biofuels 0 5 8 18 synfuels 0 0 0 0 aviation 292 298 269 258 fossil fuels 292 298 250 213 biofuels 0 0 19 45 synfuels 0 0 0 0 total (incl. pipelines) 5,881 5,665 5,029 4,335 fossil fuels 5,698 5,289 4,264 3,148 biofuels (incl. biogas) 27 156 364 447 synfuels 0 0 0 0 natural gas 67 103 114 117 hydrogen 0 1 12 114 electricity 90 117 275 510 total res 36 188 483 810 res share 1% 3% 10% 19% table 13.11.10 Oecd asia Oceania: heat supply pj/a 2012 153 140 12 0 0 172 165 7 1 0 7,249 6,234 249 27 0 30 708 0 7,573 6,540 268 27 1 30 708 0 5%

2020 151 120 31 0 0 292 216 42 31 3 6,968 5,570 570 46 26 51 704 0 7,410 5,906 643 47 57 51 704 3 14%

2025 154 112 39 1 2 473 284 125 60 4 6,536 4,673 678 241 35 97 812 0 7,163 5,069 842 243 96 97 812 4 23%

2040 2,771 984 422 0 128 360 878 131 7 3 0 121 130 87 43 0 239 179 60 0 3,277 1,257 527 0 133 360 1,000 1,625 50%

2030 192 108 57 20 8 611 274 238 88 11 6,197 3,797 763 475 65 200 897 0 7,000 4,179 1,059 495 161 200 897 11 35%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

2040 193 44 91 43 15 986 226 539 195 27 5,316 1,885 913 809 109 461 1,139 0 6,496 2,155 1,543 852 320 461 1,139 27 64%

2050 2,150 96 386 0 137 486 1,044 138 1 1 0 136 110 33 77 0 221 88 132 0 2,622 219 596 0 138 486 1,182 2,204 84%

2050 178 4 117 39 19 1,564 98 985 418 63 4,076 272 911 872 205 591 1,159 67 5,818 373 2,012 911 642 591 1,159 131 93%

[r]evolution

table 13.11.10: Oecd asia Oceania: installed capacity gw 2012 2020 total generation 458 585 fossil 297 322 hard coal (& non-renewable waste) 77 82 lignite 21 19 gas (w/o h2) 140 164 oil 57 56 diesel 2 1 nuclear 68 24 hydrogen (fuel cells, gas power plants, gas chp) 0 0 renewables 93 239 hydro 69 80 wind 6 45 of which wind offshore 0 7 pv 10 84 biomass (& renewable waste) 6 14 geothermal 1 8 solar thermal power plants 0 4 ocean energy 0 3 fluctuating res (pv, wind, ocean) 16 132 share of fluctuating res 4% 23% res share (domestic generation) 20% 41% table 13.11.12: Oecd asia Oceania: final energy demand pj/a 2012 2020 total (incl. non-energy use) 23,756 23,053 total energy use1 20,108 19,950 transport 5,881 5,665 oil products 5,698 5,289 natural gas 67 103 biofuels 27 156 synfuels 0 0 electricity 90 117 RES electricity 9 32 hydrogen 0 1 res share transport 1% 3% industry 6,564 6,615 electricity 2,235 2,439 RES electricity 225 674 public district heat 89 74 RES district heat 5 19 hard coal & lignite 1,161 1,219 oil products 1,231 1,193 gas 1,590 1,015 solar 0 11 biomass 252 619 geothermal 7 44 hydrogen 0 0 res share industry 7% 21% other sectors 7,663 7,670 electricity 3,624 3,873 RES electricity 364 1,070 public district heat 142 194 RES district heat 8 48 hard coal & lignite 81 54 oil products 1,886 1,572 gas 1,810 1,785 solar 27 35 biomass 80 141 geothermal 13 17 hydrogen 0 0 res share other sectors 6% 17% total res 1,018 2,867 res share 5% 14% non energy use 3,647 3,104 oil 3,542 3,014 gas 71 62 coal 34 28

2025 708 315 80 16 179 38 2 7 0 385 82 76 13 180 16 12 10 10 265 37% 54%

2025 21,498 18,690 5,029 4,264 114 364 0 275 114 12 10% 6,254 2,556 1,059 150 61 898 953 874 69 675 79 0 31% 7,407 3,803 1,575 224 91 40 1,180 1,734 172 229 24 0 28% 4,517 24% 2,808 2,727 56 25

2030 823 274 64 9 180 20 2 0 0 548 83 125 29 264 20 16 25 14 403 49% 67%

2030 20,090 17,377 4,335 3,148 117 447 0 510 297 114 19% 5,959 2,668 1,554 187 108 600 748 758 170 693 136 0 45% 7,082 3,647 2,124 271 156 16 852 1,595 305 325 73 0 42% 6,452 37% 2,713 2,635 54 24

2040 948 172 5 1 156 10 0 0 8 767 83 208 59 370 29 24 28 26 604 64% 81%

2050 975 65 0 0 62 3 0 0 38 872 92 223 67 394 58 30 35 40 657 67% 89%

2040 16,953 14,476 3,277 1,257 133 527 0 1,000 807 360 50% 4,967 2,521 2,035 220 180 233 340 524 232 661 236 0 67% 6,231 3,403 2,747 401 328 4 267 864 577 504 212 0 70% 9,338 65% 2,477 2,405 50 22

2050 13,781 11,537 2,622 219 138 596 0 1,182 1,139 486 84% 3,817 2,103 2,026 308 298 0 44 189 247 526 329 71 92% 5,098 2,915 2,808 511 494 0 16 153 625 558 320 0 94% 10,502 91% 2,245 2,180 45 20

1 excluding heat produced by chp autoproducers

table 13.11.13: Oecd asia Oceania: cO2 emissions mill t/a 2012 condensation power plants 998 hard coal (& non-renewable waste) 440 lignite 171 gas 254 oil 127 diesel 5 combined heat and power plants 45 hard coal (& non-renewable waste) 9 lignite 3 gas 27 oil 6 co2 emissions power and chp plants 1,043 hard coal (& non-renewable waste) 450 lignite 174 gas 281 oil & diesel 138 co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation 697 co2 intensity total electr. generation 564 co2 emissions by sector 2,214 % of 1990 emissions (1,566 mill t) 141% industry1 319 other sectors1 258 transport 439 power generation2 1,016 other conversion3 181 population (mill.) 204 co2 emissions per capita (t/capita) 10.9

2020 813 402 122 200 86 2 54 11 6 34 3 867 413 128 234 91

2025 697 381 99 162 53 2 64 14 5 44 3 762 395 104 206 58

2030 481 251 53 153 22 2 59 11 0 45 3 540 262 53 198 27

2040 153 15 5 122 10 0 42 4 0 36 1 195 20 5 158 12

2050 19 0 0 15 4 0 15 0 0 15 0 34 0 0 30 4

682 437 1,879 120% 292 232 410 836 110 206 9.1

667 374 1,571 100% 242 197 332 723 76 207 7.6

609 254 1,153 74% 191 162 247 502 51 206 5.6

447 85 464 30% 99 75 103 169 18 203 2.3

436 16 85 5% 23 11 25 24 2 199 0.4

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.11.14: Oecd asia Oceania: primary energy demand pj/a 2012 2020 total 35,801 34,550 fossil 32,365 27,621 hard coal (& non-renewable waste) 8,092 7,136 lignite 1,592 1,133 natural gas 7,667 6,323 crude oil 15,014 13,028 nuclear 1,814 1,778 1,622 5,151 renewables hydro 419 539 wind 50 468 solar 62 457 biomass (& renewable waste) 826 1,951 geothermal 266 1,703 ocean energy 0 32 of which non-energy use 3,647 3,104 net electricity imports (final energy) 0 0 total res incl. net electricity import 1,622 5,151 res share 5% 15%

2025 31,269 23,535 6,493 915 5,689 10,438 545 7,189 558 828 1,143 2,560 1,992 108 2,808 0 7,189 23%

2030 28,352 18,520 4,288 466 5,654 8,112 0 9,831 571 1,404 1,971 3,099 2,624 162 2,713 0 9,831 35%

2040 23,296 9,629 552 46 4,491 4,540 0 13,668 586 2,448 2,940 3,832 3,555 306 2,477 0 13,668 59%

2050 18,835 3,637 20 0 1,085 2,532 0 15,198 647 2,636 3,230 4,128 4,089 468 2,245 0 15,198 81%

o e c d a s i a o c e a n i a : a d va n c e d e n e r gy [ r ] e vo lu t i o n s c e n a r i o table 13.11.15 Oecd asia Oceania: electricity generation twh/a 2012 2020 1,780 1,935 515 494 144 110 570 452 0 0 194 120 7 3 166 163 35 74 116 150 14 160 0 35 10 118 9 56 0 26 0 9 69 100 7 8 2 5 53 68 0 0 5 4 2 11 0 4 0 1

33 36 1,849 1,497 521 146 623 200 7 166 0 0 186 116 14 10 37 9 0 0 78 119 0 0 1,652 23 1% 10%

42 58 2,035 1,264 502 115 520 124 3 163 1 0 608 150 160 118 85 60 26 9 83 112 7 37 1,797 287 14% 30%

2025 1,961 408 92 383 0 72 3 50 91 155 280 70 250 82 55 40 140 10 3 87 0 3 27 8 1

2030 2,112 241 50 370 0 29 3 0 88 159 450 150 370 144 120 90 166 9 0 90 0 4 50 11 2

2040 2,454 8 5 267 27 13 1 0 59 163 820 320 590 205 170 155 208 2 0 73 7 2 101 25 4

2050 2,838 0 0 128 128 0 0 0 48 180 1,020 380 758 206 250 248 245 0 0 47 47 0 136 54 8

60 80 2,100 1,062 419 95 470 75 3 50 1 0 988 155 280 250 118 90 55 40 85 100 25 27 1,863 570 27% 47%

68 98 2,278 795 250 50 460 33 3 0 2 1 1,482 159 450 370 138 155 120 90 87 90 92 24 1,986 910 40% 65%

88 120 2,662 336 10 5 306 15 1 0 38 33 2,288 163 820 590 160 230 170 155 90 73 335 119 2,045 1,565 59% 87%

110 135 3,083 0 0 0 0 0 0 0 183 183 2,900 180 1,020 758 184 260 250 248 90 59 823 220 1,891 2,026 66% 100%

table 13.11.16 Oecd asia Oceania: final energy consumption transport pj/a 2012 2020 2025 2030 road 5,244 4,912 4,276 3,421 fossil fuels 5,167 4,628 3,600 2,325 biofuels 27 146 322 319 synfuels 0 47 34 28 natural gas 51 84 88 75 hydrogen 0 10 52 214 electricity 0 44 214 487 rail 149 157 160 191 fossil fuels 59 41 25 15 biofuels 0 2 3 3 synfuels 0 1 0 0 electricity 90 113 131 173 navigation 180 173 162 151 fossil fuels 180 166 153 131 biofuels 0 5 9 18 synfuels 0 2 1 2 aviation 292 295 265 245 fossil fuels 292 292 244 199 biofuels 0 2 19 42 synfuels 0 1 2 4 total (incl. pipelines) 5,881 5,597 4,910 4,046 fossil fuels 5,698 5,127 4,022 2,671 biofuels (incl. biogas) 27 156 353 382 synfuels 0 50 37 34 natural gas 67 97 98 82 hydrogen 0 10 52 214 electricity 90 157 347 663 total res 36 221 558 975 res share 1% 4% 11% 24% table 13.11.17 Oecd asia Oceania: heat supply pj/a 2012 153 140 12 0 0 172 165 7 1 0 7,249 6,234 249 27 0 30 708 0 7,573 6,540 268 27 1 30 708 0 5%

2020 141 111 29 0 0 302 223 43 32 3 6,968 5,570 570 46 26 51 704 0 7,410 5,905 642 47 59 51 704 3 14%

2025 154 112 39 1 2 473 284 125 60 4 6,536 4,673 678 241 35 97 812 0 7,163 5,069 842 243 96 97 812 4 23%

2040 2,156 590 178 126 24 460 903 231 4 1 1 225 130 84 27 19 203 132 42 29 2,852 811 247 175 20 460 1,140 1,794 63%

2030 192 108 57 20 8 611 274 238 88 11 6,197 3,797 763 475 65 200 897 0 7,000 4,179 1,059 495 161 200 897 11 36%

1 public chp and chp autoproduction / 2 heat from ambient energy and electricity use / 3 incl. process heat, cooking

358

2040 193 44 91 43 15 986 201 543 195 47 5,316 1,763 913 809 109 461 1,139 122 6,496 2,008 1,548 852 320 461 1,139 169 67%

2050 1,521 0 51 129 0 579 890 285 0 0 1 284 110 0 31 79 172 0 49 123 2,221 0 132 331 0 579 1,178 2,221 100%

2050 202 0 137 45 21 1,523 0 911 418 194 4,093 0 711 876 205 594 1,369 338 5,818 0 1,758 921 645 594 1,369 533 100%

table 13.11.18: Oecd asia Oceania: installed capacity gw 2012 2020 total generation 458 612 fossil 297 319 hard coal (& non-renewable waste) 77 82 lignite 21 19 gas (w/o h2) 140 161 oil 57 56 diesel 2 1 nuclear 68 24 hydrogen (fuel cells, gas power plants, gas chp) 0 0 renewables 93 268 hydro 69 80 wind 6 55 of which wind offshore 0 10 pv 10 101 biomass (& renewable waste) 6 14 geothermal 1 8 solar thermal power plants 0 7 ocean energy 0 3 fluctuating res (pv, wind, ocean) 16 159 share of fluctuating res 4% 26% res share (domestic generation) 20% 44% table 13.11.19: Oecd asia Oceania: final energy demand pj/a 2012 2020 total (incl. non-energy use) 23,756 22,985 total energy use1 20,108 19,882 transport 5,881 5,597 oil products 5,698 5,127 natural gas 67 97 biofuels 27 156 synfuels 0 50 electricity 90 157 RES electricity 9 47 hydrogen 0 10 res share transport 1% 4% industry 6,564 6,615 electricity 2,235 2,439 RES electricity 225 728 public district heat 89 74 RES district heat 5 19 hard coal & lignite 1,161 1,219 oil products 1,231 1,193 gas 1,590 1,015 solar 0 11 biomass 252 619 geothermal 7 44 hydrogen 0 0 res share industry 7% 21% other sectors 7,663 7,670 electricity 3,624 3,873 RES electricity 364 1,157 public district heat 142 194 RES district heat 8 49 hard coal & lignite 81 54 oil products 1,886 1,572 gas 1,810 1,785 solar 27 35 biomass 80 141 geothermal 13 17 hydrogen 0 0 res share other sectors 6% 18% total res 1,018 3,042 res share 5% 15% non energy use 3,647 3,104 oil 3,542 3,014 gas 71 62 coal 34 28

2025 752 297 70 16 171 38 2 7 0 447 82 92 19 214 20 13 14 13 318 42% 59%

2025 21,379 18,570 4,910 4,022 98 353 37 347 163 52 11% 6,254 2,556 1,203 150 61 898 953 874 69 675 79 0 33% 7,407 3,803 1,790 224 91 40 1,180 1,734 172 229 24 0 31% 4,952 27% 2,808 2,727 56 25

2030 897 252 50 9 172 20 2 0 0 644 83 143 40 315 23 23 30 28 486 54% 72%

2030 19,924 17,211 4,046 2,671 82 382 34 663 432 214 24% 5,992 2,713 1,766 187 108 600 740 753 170 693 136 0 48% 7,173 3,772 2,455 271 156 16 831 1,581 305 325 73 0 46% 7,160 42% 2,713 2,635 54 24

2040 1,120 130 2 1 116 10 0 0 14 976 83 248 82 496 29 39 34 48 791 71% 87%

2040 16,742 14,265 2,852 811 20 247 175 1,140 994 460 63% 5,022 2,598 2,264 220 182 233 332 461 232 661 236 50 72% 6,390 3,623 3,159 401 332 4 243 747 577 504 212 80 76% 10,267 72% 2,477 2,405 50 22

2050 1,376 0 0 0 0 0 0 0 123 1,252 92 310 97 637 39 49 50 76 1,023 74% 91%

2050 13,651 11,407 2,221 0 0 132 331 1,178 1,178 579 100% 3,889 2,274 2,274 308 308 0 0 0 247 526 329 206 100% 5,297 3,360 3,360 515 515 0 0 0 630 320 322 151 100% 11,407 100% 2,245 2,180 45 20

1 excluding heat produced by chp autoproducers

table 13.11.20 Oecd asia Oceania: cO2 emissions mill t/a 2012 condensation power plants 998 hard coal (& non-renewable waste) 440 lignite 171 gas 254 oil 127 diesel 5 combined heat and power plants 45 hard coal (& non-renewable waste) 9 lignite 3 gas 27 oil 6 co2 emissions power and chp plants 1,043 hard coal (& non-renewable waste) 450 lignite 174 gas 281 oil & diesel 138 co2 intensity (g/kWh) without credit for chp heat co2 intensity fossil electr. generation 697 co2 intensity total electr. generation 564 co2 emissions by sector 2,214 % of 1990 emissions (1,566 mill t) 141% industry1 319 other sectors1 258 transport 439 power generation2 1,016 other conversion3 181 population (mill.) 204 co2 emissions per capita (t/capita) 10.9

2020 810 404 122 196 86 2 54 11 6 34 3 864 414 128 230 91

2025 640 332 99 154 53 2 64 14 5 44 3 704 345 104 198 58

2030 415 193 53 145 22 2 59 11 0 45 3 474 204 53 190 27

2040 113 6 5 92 10 0 37 3 0 33 1 150 9 5 124 12

2050 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

684 425 1,861 119% 292 232 397 833 107 206 9.0

663 335 1,491 95% 242 197 313 665 73 207 7.2

597 208 1,039 66% 190 160 209 437 44 206 5.0

447 56 360 23% 92 66 63 128 11 203 1.8

0 0 0 0% 0 0 0 0 0 199 0.0

1 incl. chp autoproducers / 2 incl. chp public / 3 district heating, refineries, coal transformation, gas transport

table 13.11.21: Oecd asia Oceania: primary energy demand pj/a 2012 2020 total 35,801 34,449 fossil 32,365 27,306 hard coal (& non-renewable waste) 8,092 6,863 lignite 1,592 1,133 natural gas 7,667 6,457 crude oil 15,014 12,853 nuclear 1,814 1,778 1,622 5,365 renewables hydro 419 539 wind 50 576 solar 62 565 biomass (& renewable waste) 826 1,949 geothermal 266 1,703 ocean energy 0 32 of which non-energy use 3,647 3,104 net electricity imports (final energy) 0 0 total res incl. net electricity import 1,622 5,365 res share 5% 16%

2025 31,081 22,486 5,505 915 5,889 10,177 545 8,050 558 1,008 1,341 2,763 2,236 144 2,808 0 8,050 26%

2030 28,680 17,061 3,172 466 5,853 7,570 0 11,619 571 1,620 2,259 3,209 3,637 324 2,713 0 11,619 41%

2040 24,404 8,073 380 46 3,611 4,036 0 16,331 586 2,953 3,588 3,691 4,955 558 2,477 0 16,331 67%

2050 20,898 2,246 20 0 46 2,180 0 18,652 647 3,673 4,551 3,712 5,176 893 2,245 0 18,652 89%

energy

o e c d a s i a o c e a n i a : i n v e st m e n t a n d e m p loy m e n t table 13.11.22: Oecd asia Oceania: investments in electricity generation unit 2012202120312041ref 2020 2030 2040 2050 fossil (w/o chp) billion $ 167.4 121.6 161.1 140.0 nuclear billion $ 179.7 244.4 267.2 270.0 chp (fossil + renewable) billion $ 101.4 45.1 66.0 32.7 renewables (w/o chp) billion $ 191.0 140.8 202.0 153.0 total billion $ 639.7 551.8 696.3 595.8 conventional (fossil & nuclear) billion $ 445.9 409.2 491.0 439.7 renewables billion $ 193.8 142.6 205.2 156.1 biomass billion $ 13.2 16.3 18.3 22.0 hydro billion $ 35.0 45.2 45.2 37.1 wind billion $ 20.5 33.4 43.5 44.6 pv billion $ 98.0 21.0 64.0 20.5 geothermal billion $ 22.4 22.0 26.7 21.6 solar thermal power plants billion $ 1.5 2.9 4.2 6.2 ocean energy billion $ 3.1 1.7 3.3 4.1 e[r] fossil (w/o chp) billion $ 141.6 56.1 90.2 98.4 nuclear billion $ 21.8 0.0 0.0 0.0 chp (fossil + renewable) billion $ 82.4 70.2 69.9 160.2 renewables (w/o chp) billion $ 430.5 705.0 606.6 614.2 total billion $ 676.4 831.3 766.7 872.9 conventional (fossil & nuclear) billion $ 234.2 94.1 109.1 105.3 renewables billion $ 442.2 737.2 657.6 767.6 biomass billion $ 25.4 32.5 54.2 135.8 hydro billion $ 62.8 47.2 37.2 64.1 wind billion $ 86.3 186.5 258.1 193.2 pv billion $ 145.1 246.1 190.9 165.8 geothermal billion $ 82.6 59.8 60.9 73.9 solar thermal power plants billion $ 22.7 108.4 15.5 84.1 ocean energy billion $ 17.3 56.7 40.8 50.7 adv e[r] fossil (w/o chp) billion $ 139.8 33.8 77.4 141.0 nuclear billion $ 21.8 0.0 0.0 0.0 chp (fossil + renewable) billion $ 82.4 70.2 70.1 76.3 renewables (w/o chp) billion $ 495.1 912.0 856.9 996.5 total billion $ 739.1 1,016.0 1,004.4 1,213.8 conventional (fossil & nuclear) billion $ 232.3 71.7 95.9 146.9 renewables billion $ 506.8 944.3 908.5 1,066.9 biomass billion $ 25.4 38.8 49.8 67.4 hydro billion $ 62.8 47.2 37.2 64.1 wind billion $ 110.3 214.4 333.8 297.7 pv billion $ 171.2 291.3 285.7 288.1 geothermal billion $ 82.6 107.6 109.8 102.5 solar thermal power plants billion $ 37.1 120.8 27.6 147.8 ocean energy billion $ 17.3 124.1 64.6 99.3

2012unit 2050 590.1 billion $/a 961.3 billion $/a 245.1 billion $/a 686.9 billion $/a 2,483.4 billion $/a 1,785.7 billion $/a 697.7 billion $/a 69.8 billion $/a 162.6 billion $/a 142.1 billion $/a 203.5 billion $/a 92.7 billion $/a 14.9 billion $/a 12.1 billion $/a

annual average

386.4 billion $/a 21.8 billion $/a 382.7 billion $/a 2,356.4 billion $/a 3,147.3 billion $/a 542.6 billion $/a 2,604.6 billion $/a 248.0 billion $/a 211.4 billion $/a 724.2 billion $/a 747.8 billion $/a 277.2 billion $/a 230.7 billion $/a 165.4 billion $/a

9.9 0.6 9.8 60.4 80.7 13.9 66.8 6.4 5.4 18.6 19.2 7.1 5.9 4.2

391.8 billion $/a 21.8 billion $/a 299.1 billion $/a 3,260.5 billion $/a 3,973.3 billion $/a 546.8 billion $/a 3,426.5 billion $/a 181.3 billion $/a 211.4 billion $/a 956.3 billion $/a 1,036.3 billion $/a 402.5 billion $/a 333.3 billion $/a 305.3 billion $/a

10.0 0.6 7.7 83.6 101.9 14.0 87.9 4.6 5.4 24.5 26.6 10.3 8.5 7.8

2012-2050 15.1 24.6 6.3 17.6 63.7 45.8 17.9 1.8 4.2 3.6 5.2 2.4 0.4 0.3

table 13.11.23: Oecd asia Oceania: investments unit 2012ref 2020 heat pumps billion $ 4.5 deep geothermal billion $ 0.0 solar thermal billion $ 10.1 biomass billion $ 24.9 total billion $ 39.5 e[r] heat pumps billion $ 8.2 deep geothermal billion $ 6.1 solar thermal billion $ 9.5 bomass billion $ 44.2 total billion $ 68.0 adv e[r] heat pumps billion $ 8.2 deep geothermal billion $ 6.1 solar thermal billion $ 9.5 biomass billion $ 44.0 total billion $ 67.9

[r]evolution

in renewable heat generation 2021203120412012unit 2030 2040 2050 2050 4.2 1.9 1.3 11.8 billion $/a 0.0 0.0 0.0 0.0 billion $/a 14.1 18.1 24.0 66.4 billion $/a 18.2 18.5 12.5 74.1 billion $/a 36.5 38.5 37.7 152.2 billion $/a

2012-2050 0.3 0.0 1.7 1.9 3.9

39.1 8.1 124.6 44.6 216.3

72.9 15.5 95.2 47.7 231.3

69.3 27.2 80.4 24.3 201.2

189.5 billion $/a 56.9 billion $/a 309.7 billion $/a 160.7 billion $/a 716.7 billion $/a

4.9 1.5 7.9 4.1 18.4

39.1 8.1 124.6 44.7 216.4

72.9 15.5 95.2 47.6 231.1

70.2 28.4 83.3 4.0 186.0

190.3 billion $/a 58.1 billion $/a 312.7 billion $/a 140.3 billion $/a 701.4 billion $/a

4.9 1.5 8.0 3.6 18.0

table 13.11.24: Oecd asia Oceania: total employment in the energy sector

thousand jobs adv e [ r ] scenariO

reference scenariO

annual average

2015 185 35 135 112 5.0 6 478

2020 123 15 158 114 11.3 7 428

2025 120 15 160 118 19.1 9 442

2030 108 10 162 123 26.9 9 438

2020 363 95 176 132 3.8 13 782

2025 387 113 233 149 2.3 108 992

2030 373 108 276 154 0.8 145 1,056

90 78 134 177 48 17 9.7 93.0 1.0 0.4 0.9 6 0.3 478

81 72 135 140 54 17 13.0 45.8 2.1 0.7 0.8 6 0.29 428

88 73 133 147 59 18 15.2 42.8 2.1 0.9 0.8 9 0.277 442

88 70 133 147 63 18 16.7 35.9 2.0 1.1 1.2 8.6 0.3 438

52 77 145 509 95 21 68 269 8.1 15.1 19 6 7 782

41 72 144 735 120 19 109 298 12.9 32.2 37 99 8 992

24 72 140 820 135 17 130 333 10.3 26.7 23.1 119 26 1,056

359

world energy [r]evolution a sustainable world energy outlook

13.5 2005 – 2015 – One decade Of energy [r]evOlutiOn scenariOs greenpeace published the first energy [R]evolution scenario in may 2005 for the eu-25 in conjunction with a 7-month long ship tour from poland all the way down to egypt. During the past 10 years, this work has developed significantly. the very first scenario was launched on board the ship with the support of former eRec policy Director oliver schäfer, the start of a long-lasting fruitful energy [R]evolution collaboration between greenpeace international and eRec. the german aerospace center’s institute for engineering thermodynamics under Dr. wolfram krewitt’s leadership has been the scientific institution behind all published energy revolutions since then as well. between 2005 and 2009, these three very different stakeholders managed to put together over 30 scenarios for countries from all continents and published two editions of the global energy [R]evolution scenario, which became a wellrespected, progressive, alternative energy blueprint. the work has been translated into over 15 different languages including arabic, chinese, french, german, hebrew, Japanese, Russian, spanish, thai and turkish.

the concept of an energy [R]evolution scenario has been under constant development ever since. today, we are able to calculate employment effects in parallel to the scenario development. the calculation program mesap/planet is from software firm seven2one, and lots of features were developed for this project. for the 2010 edition, we developed a standardised report tool, which provides us with a “ready to print” executive summary for each region and/or country we investigate. all regions also interact with each other, so the global scenario is set up like a cascade. these innovative developments serve for an ever improving quality, faster development times and more user-friendly outputs. in the past years, a team of about 20 scientists from all regions across the world came together to review regional and/or country-specific scenarios and make sure that they properly reflect their region. in some cases, these energy [R]evolutions scenarios were the first ever published as long-term energy scenario for a country, such as the turkish scenario published in 2009. since the first global energy [R]evolution scenario published in January 2007, we have held side events at every single unfccc climate conference, countless energy conferences and panel debates. over 200 presentations in more than 30 languages always had one message in common. “the energy [R]evolution is possible; it is needed and pays off for future generations!” many high level meetings took place, for example on 15 July 2009, when chilean president michelle bachelet attended our launch event for the energy [R]evolution chile. the energy [R]evolution work is a corner-stone of the greenpeace climate and energy work worldwide. we would like to thank all involved stakeholders. unfortunately, in october 2009, Dr wolfram krewitt of DLR passed away far 360

too early and left a huge gap for everybody. his energy and dedication helped to make the energy [R]evolution project a true success story. arthouros Zervos and christine Lins of eRec were involved in this work from 2005 until 2013 when eRec stopped operation. Dr. sven teske of greenpeace international developed the energy [R]evolution scenario series and has headed this global project since the first development stage in november 2004. Dr. thomas pregger, Dr. tobias naegler and Dr. sonja simon form the DLR core team responsible for modelling all energy [R]evolution scenarios since 2009. the well received layout of all energy [R]evolution documents has been done – also from the very beginning – by tania Dunster and Jens christiansen from “onehemisphere” in sweden with enormous passion, especially in the final phase when the report goes to print. over the past decade, all report texts have been written and/or edited by technical editors: crispin aubrey, alexandra Dawe, caroline chisholm and – for the latest edition – craig morris made sure that the international science team published results in easy to read english. with the third version of energy [R]evolution 2010 report, published in June 2010 in berlin, we reached out the scientific community to a much larger extent. the ipcc´s special Report Renewables (sRRen) chose the energy [R]evolution as one of the four benchmark scenarios for climate mitigation energy scenarios (discussed in this edition in chapter 5). the energy [R]evolution was the most ambitious scenario: combining an uptake of renewable energy and energy efficiency, it put forwards the highest renewable energy share by 2050. however, this high share resulted in a very strict efficiency strategy, and other scenarios actually had more renewables in terms of exajoules by 2050. following the publication of the sRRen in may 2011 in abu Dhabi, the e[R] became a widely quoted energy scenario and is now part of many scientific debates and referenced in numerous scientific peer-reviewed literatures. the fourth edition, energy [R]evolution 2012, takes into account the significantly changed situation of the global energy sector that has occurred in just two years. in Japan, the 2011 fukushima nuclear disaster following the devastating tsunami in Japan, triggered a faster phase-out on nuclear power in several countries. a serious oil spill occurred at the Deepwater horizon drilling platform in the gulf of mexico in 2010, highlighting the damage that can be done to eco-systems, and some countries are indicating new oil exploration in ever-more sensitive environments like the arctic circle. in the gas sector, there is an increase in shale gas projects, a particularly carbon-intensive way to obtain gas; it has required a more detailed analysis of the gas use projection in the energy [R]evolution. in march 2015, the energy [R]evolution received worldwide recognition when a widely circulated report from the us

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american meister consultants group concluded that the rapid market growth of renewable power generation has been largely under estimated and report that “just about no one saw it coming. the world’s biggest energy agencies, financial institutions, and fossil fuel companies, for the most part, seriously under estimated just how fast the clean power sector could and would grow”. meister identifies one group that got the market scenario closest to right, however, and it wasn’t the international energy agency or goldman sachs or the us Department of energy (Doe). “over the past 15 years, a number of predictions—by the international energy agency, the us energy information administration, and others—have been made about the future of renewable energy growth,” the meister report noted. “almost every one of these predictions has underestimated the scale of actual growth experienced by the wind and solar markets. only the most aggressive growth projections, such as greenpeace’s energy [R]evolution scenarios, have been close to accurate.” in the renewable energy sector, there has been a faster cost reduction in the photovoltaic and wind industries, creating earlier break-even points for these renewable energy investments. new and more detailed analysis of renewable energy potential is available, and new storage technologies are available, which could change the proportions of energy input types, for instance, reducing the need for bioenergy to make up the greenhouse gas reduction targets of the model. several studies independently find that solar photovoltaic power generation will be the cheapest of all power generation technologies, with cost estimations of down to 3 to 5 cents per kilowatt-hour even in central europe. in combination with new battery technology, pv has the potential to become truly disruptive for utilities. During 2013 and 2014, when the costs for renewables dropped and for the first time outpaced investments in new fossil power generation, the 100% renewable energy movement grew. more and more communities, companies and civil society now demand a transition towards a fossil and nuclear free future by 2050 – only one generation from now. this fifth edition of the energy [R]evolution presents the first global energy pathway for a complete switch to renewables and what this mean for future employment. taking the above into account, this edition of the energy [R]evolution includes: • Detailed investment pathways for power, heating and transport • Detailed employment calculations for all sectors and the development of a social plan for oil, coal and gas workers

13.6 Overview Of the energy [r]evOlutiOn campaign since 2005 greenpeace published the first energy [R]evolution scenario in may 2005 for europe. a global energy [R]evolution scenario have been published in several scientific and peer-review journals like “energy policy”. see below a selection of milestones from the energy [R]evolution work between 2005 and June 2010. June 2005: first energy [R]evolution scenario for eu 25 presented in Luxembourg for members of the eu´s environmental council July – august 2005: national energy [R]evolution scenarios for france, poland and hungary launched during an “energy revolution” ship tour with a sailing vessel across europe January 2007: first global energy [R]evolution scenario published parallel in brussels and berlin april 2007: turkish translation from the global scenario July 2007: futu[r]e investment – an analysis of the needed global investment pathway for the energy revolution scenarios november 2007: energy [R]evolution for indonesia in Jakarta / indonesia January 2008: energy [R]evolution for new Zealand in wellington / nZ march 2008: energy [R]evolution for brazil in Rio de Janeiro / brazil april 2008: energy [R]evolution for china in beijing / china June 2008: energy [R]evolution for Japan in aoi mori & tokyo/Japan June 2008: energy [R]evolution for australia in canberra / australia august 2008: energy [R]evolution for the philippines in manila/philippines august 2008: energy [R]evolution for the mexico in mexico city / mexico october 2008. second edition of the global energy [R]evolution Report December 2008: energy [R]evolution for the eu-27 in brussels / belgium December 2008. Launch of a concept for specific feed intariff mechanism to implement the global energy [R]evolution Report in developing countries at a cop13 side event in poznan / poland

• Detailed market analysis of the current power plant market

march 2009: energy washington/usa

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the

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• Detailed transport development pathway.

march 2009: energy [R]evolution for india in Delhi / india

april 2009: energy [R]evolution for Russia in moskow / Russia

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may 2009: energy [R]evolution for canada in ottawa/canada June 2009: energy [R]evolution for greece in athens/greece June 2009: energy [R]evolution for italy in Rome / italy July 2009: energy [R]evolution for chile in santiago / chile July 2009: energy [R]evolution for argentina in buenos aires /argentina september 2009. Launch of the first detailed Job analysis “working for the climate” – based on the global energy [R]evolution report in sydney/australia october 2009: energy [R]evolution for south africa in Johannesburg / sa november 2009: energy [R]evolution for turkey in istanbul / turkey november 2009: “Renewable 24/7” a detailed analysis for the needed grid infrastructure in order to implement the energy [R]evolution for europe with 90% renewable power in berlin / germany april 2010: energy [R]evolution for sweden may 2011: energy [R]evolution south africa september 2011: energy [R]evolution Japan september 2011: energy [R]evolution argentina november 2011: energy [R]evolution hungary

april 2012: energy [R]evolution for south korea June 2012: 4th edition of the global energy [R]evolution June 2012: energy [R]evolution for czech Republic october 2012: energy [R]evolution for israel october 2012: energy [R]evolution for eu 27 november 2012: energy [R]evolution for finland november 2012: energy [R]evolution for india february 2013: energy [R]evolution for new Zealand april 2013: energy [R]evolution for south korea august 2013: energy [R]evolution for brazil september 2013: energy [R]evolution for asean region november 2013: energy [R]evolution for switzerland nov 2013: energy [R]evolution for italy february 2014: energy [R]evolution for mexico april 2014: “powe[R] 2030” a detailed analysis for the needed grid infrastructure in order to implement the energy [R]evolution for europe with 75% renewable power by 2030 may 2014: energy [R]evolution for usa June 2015: energy [R]evolution for turkey

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“there are no major economic or technical barriers to moving towards 100% renewable energy by 2050.”

ottho heldringstraat 5, 1066 aZ amsterdam, the netherlands. t +31 20 718 2000 f +31 20 718 2002 greenpeace e.v., hongkongstrasse 10, 20457 hamburg, germany. info@greenpeace.de www.greenpeace.org v.i.s.d.p.: Dr. sven teske

the global Wind energy council (gWec) is the voice of the global wind energy sector. gwec works at highest international political level to create better policy environment for wind power. gwec’s mission is to ensure that wind power established itself as the answer to today’s energy challenges, producing substantial environmental and economic benefits. gwec is a member based organisation that represents the entire wind energy sector. the members of gwec represent over 1,500 companies, organisations and institutions in more than 70 countries, including manufacturers, developers, component suppliers, research institutes, national wind and renewables associations, electricity providers, finance and insurance companies. Rue d’arlon 80, 1040 brussels, belgium t +32 2 213 1897 f +32 2 213 1890 info@gwec.net www.gwec.net solarpower europe, the new epia (european photovoltaic industry association), is a member-led association representing organisations active along the whole value chain. our aim is to shape the regulatory environment and enhance business opportunities for solar power in europe. Rue d arlon 69-71b, 1040 brussels, belgium t +32 2 709 55 20 f+32 2 725 32 50 info@solarpowereurope.org www.solarpowereurope.org

greenpeace is a global organisation that uses non-violent direct action to tackle the most crucial threats to our planet’s biodiversity and environment. greenpeace is a non-profit organisation, present in 40 countries across europe, the americas, africa, asia and the pacific. it speaks for 2.8 million supporters worldwide, and inspires many millions more to take action every day. to maintain its independence, greenpeace does not accept donations from governments or corporations but relies on contributions from individual supporters and foundation grants. greenpeace has been campaigning against environmental degradation since 1971 when a small boat of volunteers and journalists sailed into amchitka, an area west of alaska, where the us government was conducting underground nuclear tests. this tradition of ‘bearing witness’ in a non-violent manner continues today, and ships are an important part of all its campaign work.

image tropical cyclone joalane swirling in the indian ocean. front cover image asia and australia at night. © nasa earth observatory image by robert simmon. front cover small images offshore wind park gunfleet sands in the north sea. © paul langrock, greenpeace. / saerbeck in north rhine westfalia is a community which owns their own wind and solar park. 70% of the private households in saerbeck are supplied by renewable energies. © bente stachowske, greenpeace.