Agora Energiewende, Wuppertal Institut (2019): Klimaneutrale Industrie: Schlüsseltechnologien und Politikoptionen für Stahl, Chemie und Zement, Berlin.
Agora Verkehrswende, Agora Energiewende, Frontier Economics (2018): Die zukünftigen Kosten strombasierter synthetischer Brennstoff, Berlin.
AHK (2020): Econet Monitor, Ausgabe August 2020, Beijing/Shanghai.
Anouti,Y., Elborai,S. et al. (2020): The dawn of green hydrogen., PwC Report.
Argus Media (2020): France to build 6.5GW electrolysis capacity by 2030; https://www.argusmedia.com/en/news/2139800-france-to-build-65gw-electrolysis-capacity-by-2030, 9.9.2020.
Arthur D. Little (2020): The future of hydrogen and e-fuels, Luxembourg.
Barclays Equity Research (2020): Hydrogen – a climate megatrend, London.
Barnes,A., Yafimava,K. (2020): EU Hydrogen Vision: regulatory opportunities and challenges, OIES Insight No.73.
Battaglia,M., Wagner,J. (2019): Impuls zur aktuellen klimapolitischen Debatte. Einschätzungen auf Basis der dena-Leitstudie Integrierte Energiewende, ewi/dena, Berlin/Köln.
BNEF (2020) Hydrogen Economy Outlook, Bloomberg Finance.
BNEF (2020a): ‘Hydrogen Economy’ Offers Promising Path to Decarbonization; https://about.bnef.com/blog/hydrogen-economy-offers-promising-path-to-decarbonization/; 30.3.2020.
Bründlinger,T., Elizalde,J. et al. (2018): dena-Leitstudie Integrierte Energiewende, Berlin.
Bukold, Steffen (2020): Blauer Wasserstoff. Perspektiven und Grenzen eines neuen Technologiepfades, Hamburg (im Auftrag von Greenpeace Energy).
BMWi (2020): Die Nationale Wasserstoffstrategie, Berlin.
Cappellen,L., Croezen,H. et al. (2018): Feasibility study into blue hydrogen, CE Delft.
Christensen, Adam (2020): Assessment of Hydrogen Production Costs from Electrolysis: United States and Europe.
Crone,K., Fasbender,S. (2019): Powerfuels – A missing link to a successful global energy transition, dena Berlin.
Deutsch,M.,Graf, A. (2019): EU-wide innovation support is key to the success of electrolysis manufacturing in Europe – Background, Agora Energiewende, Berlin.
Deutsche Energie-Agentur (2018): Heutige Einsatzgebiete für Power Fuels. Factsheets zur Anwendung von klimafreundlich erzeugten synthetischen Energieträgern, Berlin.
Dickel, Ralf (2020): Blue hydrogen as an enabler of green hydrogen: the case of Germany, OIES Paper NG 159.
Energy Brainpool, Wuppertal Institut (2019): Erneuerbar in allen Sektoren – Zusammenfassung neuer Studien und Vorschläge. Bedarf an Strom und Wasserstoff (Windgas) für ein klimaneutrales Deutschland, Hamburg/Berlin.
EnergyComment (2020): Global Energy Briefing 2020, lfd. Ausgaben.
Europäische Kommission (2019): Der europäische Grüne Deal, COM(2019) 640 final, Brüssel.
European Commission (2020): A hydrogen strategy for a climate-neutral Europe, COM(2020) 301 final, Brussels.
FCH-JU (2019): Hydrogen Roadmap Europe. A sustabinable pathway for the European energy transition, Luxemburg.
Franke, Andreas (2019): Green hydrogen faces high hurdles, massive potential: IRENA report https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/092719-green-hydrogen-faces-high-hurdles-massive-potential-irena-report
Frankfurt School-UNEP / BNEF (2020): Global Trends in Renewable Energy Investment 2020, Frankfurt.
Fuel Cell and Hydrogen Energy Association (2020): Roadmap to a US Hydrogen Economy, Washington D.C.
Gallagher, Ben (2020): Hydrogen production costs: is a tipping point near?, WoodMackenzie.
Gas for Climate (2020): Response to the Commission consultation on energy system integration, www.gasforclimate2050.eu.
Gérard,F., Michalski,J. (2020): Opportunities for Hydrogen Energy Technologies considering the National Energy & Climate Plans. Final Report, Trinomics/LBST, Rotterdam.
Gerbert,Ph., Herhold,P. (2018): Klimapfade für Deutschland, BCG/Prognos, im Auftrag des BDI.
Geres, R., Kohn,A. et al. (2019): Roadmap Chemie 2050, Dechema/FutureCamp, Frankfurt/München.
Gerhardt,N., Bard,J. et al. (2020): Wasserstoff im zukünftigen Energiesystem: Fokus Gebäudewärme, Fraunhofer IEE, Hannover.
Gielen,D., Taibi,E. et al. (2019): Hydrogen: A renewable energy perspective, IRENA, Abu Dhabi.
GGFR/World Bank (2020): Global Gas Flaring Tracker Report, Washington D.C.
Gigler, J., Weeda,M. (2018): Outlines of a Hydrogen Roadmap, TKI Nieuw Gas.
Goodall, Chris (2020): https://www.carboncommentary.com/blog/2020/1/14/the-extra-costs-of-decarbonised-steel, 14.1.2020.
Greentechmedia (2020): World’s Largest Green Hydrogen Project Unveiled in Saudi Arabia; https://www.greentechmedia.com/articles/read/us-firm-unveils-worlds-largest-green-hydrogen-project, 7.7.2020.
Guidehouse (Navigant) (2020): Gas Decarbonisation Pathways 2020–2050, Gas for Climate.
Hebling,C., Ragwitz,M. et al. (2019): Eine Wasserstoff-Roadmap für Deutschland, Fraunhofer Karlsruhe/Freiburg.
Heinemann,Ch.,Kasten,P. et al. (2019): Die Bedeutung strombasierter Stoffe für den Klimaschutz in Deutschland, Öko-Institut, Freiburg.
Hermann,H., Emele,L. et al. (2014): Prüfung der klimapolitischen Konsistenz und der Kosten von Methanisierungsstrategien, Oko-Institut, Berlin/Freiburg.
Howarth,Robert (2019): Is Shale Gas a Major Driver of Recent Increase in Global Atmospheric Methane?’ Biogeosciences Discussions, April, S.1–23.
Huneke,F., Linkenheil,C. et al. (2017): Impulspapier – Experimentierklausel Power-to-Gas, Berlin.
Huneke,Fabian (2018): Auf dem Weg in die Wettbewerbsfähigkeit: Elektrolysegase erneuerbaren Ursprungs, Energy Brainpool, Berlin.
H-Vision (2019): Feasibility study report – Blue hydrogen as accelerator and pioneer for energy transition in the industry.
H2-View 2020: Fossil-free steel project ready for operation; https://www.h2-view.com/story/fossil-free-steel-project-ready-for-operation/; 27.8.2020.
Hydrogen Council (2020): Path to hydrogen competitiveness. A cost perspective.
Hydrogen Europe (2019): Green Hydrogen Investment und Support Report, Brussels.
IEA (2018a): Five keys to unlock CCS investment, Paris.
IEA (2018b): World Energy Outlook 2018, Paris.
IEA (2018c): The Future of Petrochemicals, Paris.
IEA (2019a): CCUS in Industry and Transformation.
IEA (2019b): IEA G20 Hydrogen Report – Assumptions, Paris.
IEA (2019c): The Future of Hydrogen – Seizing today’s opportunities. Report prepared by the IEA for the G20, Japan, Paris.
IEA (2019d): Transforming Industry through CCUS, Paris.
IEA (2020a): World Energy Outlook 2020, Paris.
IEA (2020b): The oil and gas industry in energy transitions, Paris.
IEA (2020c): Iron and Steel Technology Roadmap, Paris.
IEA (2020d): Special Report on Carbon Capture Utilisation and Storage. CCUS in clean energy transitions, Paris.
IEA (2020e): Energy Technology Perspectives 2020, Paris.
IEA (2020f): Themenwebseiten https://www.iea.org/reports/flaring-emissions; sowie https://www.iea.org/reports/methane-emissions-from-oil-and-gas.
IEAGHG (2017): Techno-Economic Evaluation of SMR Based Standalone (Merchant) Plant with CCS, 2017/02, Paris.
IRENA (2019): Hydrogen. A Renewable Energy Perspective, Abu Dhabi.
Jensterle,M., Narita,J. et al. (2019): The role of clean hydrogen in the future energy systems of Japan and Germany. Berlin.
Jensterle,M., Narita,J. et al. (2020): Grüner Wasserstoff: Internationale Kooperationspotenziale für Deutschland, Berlin.
Joas,F., Witecka,W. et al. (2019): Klimaneutrale Industrie: Schlüsseltechnologien und Politikoptionen für Stahl, Chemie und Zement; Agora Energiewende/Wuppertal Institut, Berlin.
Lohmann, Heiko (2020): energate Gasmarkt Oktober 2020, Berlin.
Kasten, Peter (2020): E-Fuels im Verkehrssektor, Öko-Institut, Berlin.
Kemmler,A., Kirchner,A. et al. (2020): Energiewirtschaftliche Projektionen und Folgeabschätzungen 2030/2050 (“Klimagutachten”) Prognos/Fraunhofer/GWS/iinas.
Lambert, Martin (2020a): Hydrogen und decarbonsation of gas: false down or silver bullet, OIES Insight No.66.
Lambert, Martin (2020b): EU Hydrogen Strategy, OIES Comment.
Laszly,Varro (2018): Carbon capture, utilisation and storage finally catches the spotlight. https://www.iea.org/commentaries/carbon-capture-utilisation-and-storage-finally-catches-the-spotlight Laszlo.
Lechtenböhmer, S., Peter,F. (2019): Technologie- und Politikoptionen für eine klimaneutrale Grundstoffindustrie. Handlungsoptionen für die Stahl-, Zement- und Chemieindustrie, Wuppertal Institut/Agora Energiewende, Berlin/Wuppertal.
Lechtenböhmer,S., Samadi,S. et al. (2019): Grüner Wasserstoff, das dritte Standbein der Energiewende? Energiewirtschaftliche Tagesfragen 69.Jg. (2019) Heft 10, S.10-13.
Le Fevre, Chris (2017): Methane Emissions: from blind spot to spotlight, OIES Paper NG 122.
Material Economics (2019): Industrial Transformation 2050. Pathways to Net-Zero Emissions from EU Heavy Industry, Cambridge.
Mathis,W., Thornhill,J (2019): Hydrogen’s Plunging Price Boosts Role as Climate Solution, Bloomberg; https://www.bloomberg.com/news/articles/2019-08-21/cost-of-hydrogen-from-renewables-to-plummet-next-decade-bnef, 22.8.2019.
Merten,F., Lechtenböhmer,S. (2020): Infrastructure needs for deep decarbonisation of heavy industries in Europe, Wuppertal Institut Policy Brief, Wuppertal/Berlin.
Michalski,J., Altmann,M. (2019): Wasserstoffstudie Nordrhein-Westfalen, LBST Ottobrunn.
Navigant 2019: Gas for Climate. The optimal role for gas in a net-zero emissions energy system, Utrecht.
Niggemeier,M., Linkenheil,C. (2019): Erneuerbar in allen Sektoren – Sektoren koppeln mit Power-to-Gas, Energy Brainpool, Berlin.
NPM Nationale Plattform Zukunft der Mobilität (2020): Roadmap PtX, AG 5.
Piantieri,C., Westbroek,M. (2020): Hydrogen in the Northwest European energy system, Aurora Energy Research.
Perner,J., Bothe,D. (2018): International aspects of a Power-to-X roadmap, World Energy Council/Frontier Economics.
Phadke,A., Aggarwal,S. et al. (2020): Illustrative pathways to 100 percent zero carbon power by 2035 without increasing customer costs, Energy Innovation, San Francisco.
Platts/S&P Global (2020a): Methodology and specifications guide: Hydrogen (April-Version und Oktober-Version).
Platts (2020b): UK should focus on green hydrogen opportunity to integrate offshore wind: report; https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/090920-uk-should-focus-on-green-hydrogen-opportunity-to-integrate-offshore-wind-report, 9.9.2020.
Platts (2020c): Renewable hydrogen projects ‚at risk of government inaction, capital shortfall’; https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/082420-renewable-hydrogen-projects-at-risk-of-government-inaction-capital-shortfall, 24.8.2020.
Platts (2020d): Global hydrogen demand dip this year reflects reduced refinery runs: Platts Analytics; https://www.spglobal.com/platts/en/market-insights/latest-news/agriculture/082520-global-hydrogen-demand-dip-this-year-reflects-reduced-refinery-runs-platts-analytics, 20.8.2020.
Platts (2020e): France cranks up hydrogen plans with 6.5-GW, 2030 target, plays down new nuclear; https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/090820-france-cranks-up-hydrogen-plans-with-65-gw-2030-target-plays-down-new-nuclear; 8.9.2020.
Platts (2020f): In northern China’s hydrogen push, by-product output and renewables lead the way; https://www.spglobal.com/platts/en/market-insights/blogs/oil/070720-in-northern-chinas-hydrogen-push-by-product-output-and-renewables-lead-the-way; 7.7.2020.
Platts (2020g): Blue and green hydrogen essential for energy transition, but key challenges remain: bank, https://www.spglobal.com/platts/en/market-insights/latest-news/electric-power/101920-blue-and-green-hydrogen-essential-for-energy-transition-but-key-challenges-remain-bank; 19.10.2020.
Platts (2020h): Platts Hydrogen Assessments; https://www.spglobal.com/platts/en/our-methodology/price-assessments/natural-gas/hydrogen-price-assessments.
Por, Yong-Liang (2020): Great Expectations. Asia, Australia and Europe Leading Emerging Green Hydrogen Economy, but Project Delays Likely, IEEFA.
Purr,K., Günther,J. et al. (2019): Wege in eine ressourcenschonende Treibhausgasneutralität. RESCUE – Studie, UBA, Dessau-Roßlau.
Ram,M., Fell.,H.-J. (2019): Global Energy System based on 100% Renewable Energy – Power, Heat, Transport and Desalination Sectors, Lappeenranta University of Technology/ Energy Watch Group, Lappeenranta/Berlin.
Reuters (2020): Canada has big plans to use hydrogen to cut emissions – and produce more oil; https://www.reuters.com/article/canada-hydrogen/canada-has-big-plans-to-use-hydrogen-to-cut-emissions-and-produce-more-oil-idUKL1N2FY17G; Reuters 4.9.2020.
Robinius,M., Linßen,J. et al. (2018): Comparative Analysis of Infrastructures: Hydrogen Fueling and Electric Charging of Vehicles, Forschungszentrum Jülich.
Rogers,G., Schuwerk,R. (2020): Billion Dollar Orphans, Carbon Tracker Report.
Rudolph,F., Merten,,F. et al. (2019): Strom- und H2-Bedarf für einen dekarbonisierten Verkehrssektor in Deutschland, Wuppertal Institut (im Auftrag von GP Energy), Wuppertal.
Russ,Manfred (2017): GHG Intensity of Natural Gas Transport. Comparison of Additional Natural Gas Imports to Europe by Nord Stream 2 Pipeline and LNG Import Alternatives, Thinkstep.
Rystad Energy (2020): Europe could see $35 billion in CCS spending till 2035, with most capacity coming in the UK, https://www.rystadenergy.com/newsevents/news/press-releases/europe-could-see-$35-billion-in-ccs-spending-till-2035-with-most-capacity-coming-in-the-uk/, 7.9.2020.
Schneider,Clemens et al. (2019): Klimaneutrale Industrie: Ausführliche Darstellung der Schlüsseltechnologien für die Branchen Stahl, Chemie und Zement, Agora Energiewende.
Schütz,S., Härtel,P. (2016): Klimaschutz und regenerativ erzeugte chemische Energieträger – Infrastruktur und Systemanpassung zur Versorgung mit regenerativen chemischen Energieträgern aus in- und ausländischen regenerativen Energien, DBI/Fraunhofer-IWES.
Schenuit,C., Heuke,R. et al. (2016): Potenzialatlas Power to Gas, dena 2016.
Seelos, Christian (2020): Die Wasserstoff-Transportkosten sind der Knackpunkt, Energate Messenger 1.9.2020.
Smolinka,T., Wiebe,N. et al. (2018): Industrialisierung der Wasserelektrolyse in Deutschland: Chancen und Herausforderungen für nachhaltigen Wasserstoff für Verkehr, Strom und Wärme, NOW/Fraunhofer.
SSAB 2019: SSAB Capital Markets Day 2019, Stockholm.
Sterchele,P., Brandes, J. et al. (2020): Wege zu einem klimaneutralen Energysystem, Fraunhofer ISE, Freiburg.
Stern,Jonathan (2019): Narratives for Natural Gas in an Decarbonising European Energy Market, OIES NG141.
Sterner, M., Thema, M. et al. (2015): Bedeutung und Notwendigkeit von Windgas für die Energiewende in Deutschland, FENES/OTH Regensburg/Energy Brainpool.
Sterner,M., Stadler,I. (Hrsg.) (2017): Energiespeicher – Bedarf, Technologien, Integration, 2.Aufl., Berlin/Heidelberg.
Terlouw,W., Peters,D. et al. (2019): Gas for Climate. The optimal role for gas in a net-zero emissions energy system, Navigant Utrecht.
Trinomics/LBST (2020): Opportunities for Hydrogen Energy Technologies considering the National Energy & Climate Plans, Rotterdam.
Van Wijk,A., Wouters ,F. (2019): Hydrogen – The Bridge between Africa and Europe, Delft/Masdar City.
Van Wijk,A., Chatzimarkakis,J. (2020): Green Hydrogen for a European Green Deal. A 2×40 GW Initiative, Brussels.
Wachsmuth,J., Degünther,Ch. (2019): Roadmap Gas für die Energiewende – Nachhaltiger Klimabeitrag des Gassektors, Fraunhofer/KIT, Karlsruhe.
Wagner, Elbing & Co. (2020): Commit to Connect 2050. Zielbild Energieinfrastrukturen für Ostdeutschland Endbericht, Wien.
Wassink,Jos (2019): How clean is hydrogen really? https://www.delta.tudelft.nl/article/how-clean-hydrogen-really
Westphal,K., Dröge,S. et al. (2020): Die internationalen Dimensionen deutscher Wasserstoffpolitik, SWP Berlin.
Wilkes,W., Dezem,V. et al. (2019): How ‘green hydrogen’ could make ‘green steel’ real. https://www.bloomberg.com/professional/blog/how-green-hydrogen-could-make-green-steel-real/ Download am 22.12.2019
Wissenschaftliche Dienste Deutscher Bundestag (2019): Wasserstoffstrategien – National und international, WD8-3000-134/19, Berlin.
Wood Mackenzie (2019): Green hydrogen production: Landscape, projects and costs, Executive Summary.
Wuppertal Institut / ECF (2020a): Workshop report for the region of North-West-Europe (Deliverable 4.4), Wuppertal.
Wuppertal Institut (2020b): CO2-neutral bis 2035: Eckpunkte eines deutschen Beitrags zur Einhaltung der 1,5-°C-Grenze. Bericht. Wuppertal.
Zugehör, Daniel (2020): LKW-Verkehr benötigt 140 Wasserstofftankstellen; https://www.energate-messenger.de/news/206248/lkw-verkehr-benoetigt-140-wasserstofftankstellen, energate messenger 9.10.2020.