1、Renewables2021Analysis and forecast to 2026Renewables 2021 Abstract Analysis and forecasts to 2026 PAGE | 3 IEA. All rights������ reserved. Abstract Renewables 2021 is the IEAs primary analysis on the sector, based on current policies and market developments. It forecasts the deployment of renewable energ
2、y technologies in electricity, transport and heat to 2026 while also exploring key challenges to the industry and identifying barriers to faster growth. Renewables are the backbone of any energy������� transition to achieve net zero. As the world increasingly shifts away from carbon emitting fossil fuels,
3、understanding the current role renewables play in the decarbonisation of multiple sectors is key to ensuring a smooth pathway to net zero. While renewab���les continued to be deployed at a strong pace during the Covid-19 crisis, they face new opportunities and challenges. This years report frames curre
4、nt policy and market dynamics while placing the recent rise in energy and commodities prices in context. In addition to providing detailed market analysis and forecasts, Re������newables 2021 also explores trends to watch including storage, producing hydrogen from renewable electricity, stimulus packages,
5、 aviation biofu�����els and residential heating. Renewables 2021 Acknowledgements Analysis and forecasts to 2026 PAGE | 4 IEA. All rights reserved. Acknowledgements, contributors an�������d credits This study was prepared by the Renewable Energy Division in the Directorate of Energy Markets and Security. It was
6、 designed and directed by Heymi Bahar, Senior Analyst. The report benefited from analysis, drafting and input from multiple colleagues. The lead authors of the report were, Yasmina Abdelilah, ������Heymi Bahar, Trevor Criswell, Piotr Bojek, Franois Briens, Jeremy Moorhouse and Grecia Rodrguez Jimnez, who
7、was also responsible for data management. The report also benefited from analysis and drafting from ��������Kazuhiro Kurumi and Kartik Veerakumar. Paolo Frankl, Head of the Renew�����able Energy Division, provided strategic guidance and input to this work. Valuable comments, feedback and guidance were provided b
8、y other senior management and numerous other colleagues within the IEA, in particular, Keisuke Sadamori and Laura Cozzi. Other IEA colleagues who have made important contributions to this work include: Nadim Abilllama, Ali Al-Saffar, Carlos Alvarez Fernandez, Luc����ila Arboleya, Elisa Asmelash, Praveen
9、 Bains, Christophe Barret, Jose������, Bermudez Menendez, Sylvia Beyer, Toril����� Bosoni, Stphanie Bouckaert, Davide dAmbrosio, Peter Fraser, Astha Gupta, Ilkka Hannula, Csar Alejandro Hernandez, Joerg Husar, Kevin Lane, Stefan Lorenczik, Dionisia Lyngopoulou, Yannick Monschauer, Apostolos Petropoulos, Kristi
10、ne Petrosyan, Uwe Remme, Luis Fernando Rosa, Michael Oppermann, Gabriel Saive, Jacopo Tattini, Jaco��������b Teter, Nicole Thomas, Aad Van Bohemen, Peerapat Vithayasrichareon, Timothy Goodson, Ariane Millot, Fabian Voswinkel, Brent Wanner, Daniel Wetzel. Timely data from the IEA Energy Data Centre were fund
11、amental to the report, with particular assistance �����provided by Mathilde Daugy, Julia Guyon, Nick Johnstone, Julian Prime, Cline Rouquette an�������d Roberta Quadrelli. This work benefited from extensive review and comments from the IEA Standing Group on Long-Term Co-operation, IEA Renewable Energy Working P
12、arty, members of the Renewable Industry Advisory Board (RIAB) and experts from IEA partner countries and other international institutions. The work also benefited from Renewables 2021 Acknowledgeme������nts Analysis and forecasts to 2026 PAGE | 5 IEA. All rights reserved. feedback by the IEA Committee on
13、Energy Research and Technology, IEA Technology Collaboration Programmes (IEA TCPs). Many experts from outside of the �������IEA������� provided valuable input, commented and reviewed this report. They include: Countries: Austria (Austrian Energy Agency), Belgium (Federal Public Service Economy), Brazil (Empresa d
14、e Pesquisa Energtica), Canada (Natural Resources Canada), Chile (Ministry of Energy), Peoples Republic of China (Energy Research Institute ERI), Colombia (Unidad de Planeacin Minero Energtica), European Union (European Commission DG Energy), Finland ( Ministry of Economic Affairs and Employment��������), Fr
15、ance (Ministry of Ecological and Solidarity Transition), Italy (Nat�����ional Agency for New Technologies, Energy and Sustainable Economic Development ENEA), Ireland (Sustainable Energy Authority SEAI), Japan (Ministry of Economy, Trade and Industry - METI), Spain (Institute for Energy Diversification an
16、d Energy Saving - IDAE), Switzerland (Federal Office of Energy), United Stat�����es (Department of Energy). Technology Coll��������aboration Programme (TCPs): Bioenergy TCP, Heat Pumping Technologies (HPT) TCP, Hydropower TCP, Photovoltaic Power Systems (PVPS) TCP, Solar Heating and Cooling TCP, SolarPACES TCP,
17、Wind Energy TCP. Other Organisations: Abengoa Solar, Acciona Energa, American Clean Power Association (ACPA), American Wind Energy Association (AWEA), Amrock Pty Ltd, Australian Energy Market Operator (AEMO), Council on Energy, Environment and Water (CEEW), Electric Power Developmen�����t Company (JPOWER
18、), lectricit de France (EDF), ENEL, Energy Insights Ltd, European Bank for Reconstruction and Development (EBRD), European Commission, European Geothermal Energy Association (EGEC), European Bioenergy (AEBIOM), EA Energy Analyses, European������ Heat Pump Association (EHPA), European heating industry (EHI
19、), European Renewable Energy Foundation (EREF), European Renewable Ethanol Association (EPURE), European Solar The������rmal Indu������stry Federation (ESTIF), First Solar, FTI Consulting, General Electric (GE), Gestore dei Servizi Energetici (GSE). Global Wind Energy Association (GWEC), Iberdrola, Institute of
20、 Energy Economics Japan (IEEJ), International Hydropower Association (IHA), International Renewable Energy Agency (IRENA), National Renewable Energy Laborat�������ory (NREL), Neste, rsted, POET, Queens University, REN21, Siemens Renewables 2021 Acknowledgements Analysis and forecasts to 2026 PAGE | 6 IEA.
21、All rights reserved. Gamesa, Solar Power Europe, SPV Market �������Research, TECSOL, SOLISART, United Nations Economic Commission for Europe (UNECE), US Grains Council, Universit Degli Studi di Firenze, Vestas, WindEurope, World Bank, World Bioenergy Association. The authors would also like to thank Justin
22、 Fr�����ench-Brooks for skilfully editing the manuscript and the IEA Communication and Digital Office, in particular Jon Custer, Astrid Dumond, Merve Erdem, Christopher Gully, Jad Mouawad, Barbara Moure, Jethro Mullen, Julie Puech, Robert Stone and Therese Walsh for their assistance. ������In addition, Ivo Let
23、r�����a from the Office of Management and Administration supported data management. Questions or comments? Please write to us at IEA-REMRiea.org Renewables 2021 Tables of contents Analysis and forecasts to 2026 PAGE | 7 IEA. All rights reserved. Table of contents Executive summary . 14 Improved policies
24、and COP26 climate goals are set to propel renewable electricity growth to new heights . 14 Despite rising prices, solar PV will set new records and wind will grow faster than over the previous five years . 15 Asia is set to overtake Europe a�����s India and Indonesia lead renewed growth in global demand
25、for biofuels . 16 Renewable heat has gained s�������������ome policy momentum, but its market share is not set to increase significantly . 16 High commodity and energy prices bring significant uncertainties . 17 Supported by the right policies, recovery spending on renewables could unleash a huge wave of private
26、 capital . 18 Faster growth of renewables is wi������thin reach but requires addressing persistent challenges . 18 Renewables penetration in to hard-to-decarbonise sectors is slowly emerging and promises a bright future . 19 Renewables need to grow faster than���� our forecasts to close the gap with a pathway
27、 to net zero by 2050. 19 Chapter 1. Renewable electricity . 21 Forecast summary . 21 Renewa��������ble capacity additions are set to grow faster than ever in the next five years, but the expansion trend is not on track to meet the IEA Net Zero by 2050 Scenario . 21 Growing policy momentum worldwide is drivi
28、ng our forecast upward . 22 Government-led auction capacity is in slight decline, but is compensated by robust corporate PPA activity . 24 Top-10 countries continue to dominate renew�������ables expansion, indicating that more diversity is neede������d . 25 Solar PV breaks new records in our forecast, despite ri
29、�������sing prices . 26 Low wind conditions and droughts in key markets hamper more rapid growth of renewable generation in 2021 . 30 Achieving the IEA Net Zero by 2050 Scenario requires policy makers to significantly increase their ambition for all renewables . 34 Country and regional analysis . 35 China
30、. 35 United States .���� 37 Asia Pacific . 40 India . 41 Japan . 45 Korea . 46 ASEAN . 47 Australia . 50 Renewables 2021 Tables of contents Analysis and forecasts to 2026 PAGE | 8 IEA. All rights reserved. Europe . 52 Germany . 54 Spain . 56 France . 58 The Netherlands . 60 Turkey . 62 Poland . 64 Italy
31、 . 65 United Kingdom . 67 Denmark . 68 Belgium . 69 Latin America . 71 Sub-Saharan Africa . 78 Middle East and Nort������h Africa . 81 References . 84 Chapter 2. Biofuels . 89 Forecast summary . 89 Biofuels recover in 2021 despite high costs . 89 Asia to surpass European biofuel produc���tion before 2026 . 9
32、0 Ethanol and renewable diesel lead biofuels growth . 91 Four policy discussions to watch that will help double biofuel growth rates . 91 Demand and supp������ly . 93 Asia surpasses European biofuel demand and supply . 95 Different fuels for different parts of the world . 96 Fuel demand and government pol
33、icies are driving different supply outcomes in different regions . 98 Biofuel demand growth doubles in the accelerated case . 102 Biofuels need to expand fa�������ster to align with the IEA Net Zero by 2050 Scenario . 105 Trade . 107 Renewable diesel and biojet lead growth in net trade . 108 �������Singapore clim
34、bs �������to second largest exporter, while top importers remain the same . 109 Ethanol and biojet import demand drive���s trade growth in the accelerated case . 110 References . 111 Chapter 3. Renewable heat . 114 Recent trends . 114 Global progress on conversion to renewable heat has been limited . 114 Poli
35、cy update . 115 Renewable heat has gained some policy momentum, but not enough to put the heat sector on track to meet climate ambitions . 115 Outlook to 2026 . 122 Renewables 2021 Tables of contents Analysis and forecasts to 2026 PAGE | 9 IEA. All rights reserved. Buildings����� . 123 Industry . 125 Ref
36、erences . 129 Chapter 4. Renewable energy trends to watch . 133 What is the impac���t of increasing commodity and energy prices on solar PV, wind and biofuels? . 133 Wind and solar PV . 133 How do commodity prices affect the investment costs of solar PV and onshore wind? . 134 Rising energy prices and
37、trade policies put additional upward price pressure on wind and solar . 138 Despite rising equipment prices, wind and solar remain competitive . 140 How much will renewable energy benefit from global stimulus packages? . 145 Focus on the EU Recovery������� and Resilience Facility . 148 Could the green hydr
38、ogen boom lead to additional renewable capacity by 2026? . 151 How rapidly will the global electricity storage market grow ������by 2026? . 154 Are conditions right for biojet to take flight over the next five years? . 157 Condition 1 Confidence in biojet . 158 Condition 2 Costs . 159 Condition 3 Policies
39、 . 160 Condition 4 Production . 161 Condition 5 Feedstock sustainab�����ility . 162 Are renewable heating options cost-competitive with fossil fuels in the residential sector?. 163 Upfront costs . 163 Operating costs . 165 Overall cost-competitiveness of heating technologies . 166 References . 168 Genera
40、l annex . 172 Abbreviations and acronyms. 172 Units of measure . 173 List of box����es Box 2.1 India has tripled ethanol demand over the past five years, putting it on track to be the worlds third-largest ethanol consumer by 2026 . 100 List of figures Average annual renewable capacity additions and cumu
41、lative installed capacity, historical, forecasts and IEA Net Zero Scenario, 2009-2026�������� . 22 Renewables 2021 Tables of contents Analysis and fo������recasts to 2026 PAGE | 10 IEA. All rights reserved. IEA five-year renewable capacity forecasts by country/region, main case, 2021 and 2021 . 23 Renewable elect
42、ricity auctioned capacity by country/region, 2015-2021 (left) and by technology and corporate PPAs, 2015-2021 (right) . 24 Auction-awarded renewable capacity by contract durati������on, 2017-2021 . 25 Top-ten countries share of total installed ren�������ewable capacity, historical and main case forecast, 1991-20
43、26 . 26 Annual capacity additions of solar PV, wind and other renewables, main and accelerated cases, 2020-2026 . 27 Solar PV and onshore wind capacity �����additions, actual and forecast by country/region, 2015-2026 . 28 Hydropower and wind electricity generation growth in selected����� markets, 2015- 2020 a
44、verage and 2021 . 30 Renewable electricity generation by technology, 1990-2026 (left) and share by technology, 1990-2026 (right) . 31 Share of wind, solar PV, hydropower and all re��newables in total electricity generation, 2000-2026 . 32 Wind and solar PV generation curtailment by country . 33 Averag
45、e annual capacity additions by technology, actual, forecasts and IEA Net Zero Scenario, 2015-2026 . 34 China renewable capacity additions, 2009-2026 (left) and non-fossil energy target pro������posals for 2030 (right) . 35 United States renewable capacity additions, 2008-2026 (left) and solar PV and wind
46、PPA capacity and average contract price, 2014-2020 (right) . 37 United States solar and wind capa�����city additions, 2017-2026 (left) and low-carbon ele������ctricity target, 2020-2030 (right) . 39 Asia Pacific renewable capacity additions by country, 2019-2026 (left) and capacity additions by technology, 201
47、5-2026 (right) . 41 India renewable capacity additions, 2009-2026 (left) and national t�������argets for 2022 and 2030 (right) . 42 India renewable capaci���ty awarded via auctions, 2018-2021 (left) and DISCOMs overdue payments to generators, 2019-2021 (right) . 43 Japan renewable capacity additions, 2009-202
48、6 (left) and renewable energy capacity targets, 2019-2030 (right) . 45 Korea renewable capacity additions, 2009-2026 (left) and average revenue per MWh by technology, 2017-2020 (right) . 47 ASEAN renewable capacity additio������ns by country, 2019-2026 (left) and capacity additi�����ons by technology, 2015-202
49、6 (right) . 49 Australia renewable capacity additions, 2009-2026 (left) and renewables curtailment, Q1 2019-Q2 2021 (right) . 50 EU member states installed renewable capacity and capacity expected in 2030 based on submitted NECPs . 52 Europ������e renewable capacity additions by country, 2009-2026 (left)
50、and capacity growth by technology, 2015-2026 (right) . 54 Germany renewable capacity additions, 2019-2026 (left) and onshore wind auctions (right) . 55 Spain renewable capacity additions, 2019-2026 (left) and �����comparison of auction prices and wholesale electricity prices, 2018-2021 (right) . 57 Franc
sgpjbg002
工作日 8:30 - 17:30
会员动态:
报告分类
新质生产力
ChatGPT
新能源汽车
大模型
Sora
机器人
微短剧
芯片
薪酬
白皮书
低空经济
数据要素
创新药
人工智能
AI产业
信息科技
互联网
消费经济
汽车交通
电商零售
传媒娱乐
医药健康
投资金融
能源环境
地产开发
传统产业
全球化
其它
扫码登录
手机快捷登录
账号登录
