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Technological learning and the future of solar H2: A component learning comparison of solar thermochemical cycles and electrolysis with solar PV

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  • Nicodemus, Julia Haltiwanger

Abstract

This analysis uses component learning curves to investigate the effect of policy support on the future potential of two methods of producing hydrogen using solar energy: solar thermochemical cycles and electrolysis with solar photovoltaics. The impact of policy support for photovoltaics, electrolysis, concentrated solar power, and thermochemical reactors is assessed. The rates of growth of the four technologies are taken as proxies for the degree of policy support. Key assumptions are identified and results are considered over the range of reasonable assumptions. Initially, electrolysis with PV will be the less expensive way to produce solar hydrogen. However, though it is initially more expensive, the thermochemical cycle has greater long-term potential for cost reductions from learning, and it is the faster route to $2/kg hydrogen. Cost reductions in hydrogen from the thermochemical cycles are primarily driven by improvements in the thermochemical reactors, which, due to initially high costs, will only see growth through government support. Thus, policymakers must support the thermochemical cycles through their research, development, and early implementation stages in order to achieve these cost reductions. Though the details change when key parameters are varied over their range of reasonable values, the broad conclusions are unaffected.

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  • Nicodemus, Julia Haltiwanger, 2018. "Technological learning and the future of solar H2: A component learning comparison of solar thermochemical cycles and electrolysis with solar PV," Energy Policy, Elsevier, vol. 120(C), pages 100-109.
    • Handle: RePEc:eee:enepol:v:120:y:2018:i:c:p:100-109
    DOI: 10.1016/j.enpol.2018.04.072
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    2. Massimo Moser & Matteo Pecchi & Thomas Fend, 2019. "Techno-Economic Assessment of Solar Hydrogen Production by Means of Thermo-Chemical Cycles," Energies, MDPI, vol. 12(3), pages 1-17, January.
    3. Kong, Hui & Wang, Jian & Zheng, Hongfei & Wang, Hongsheng & Zhang, Jun & Yu, Zhufeng & Bo, Zheng, 2022. "Techno-economic analysis of a solar thermochemical cycle-based direct coal liquefaction system for low-carbon oil production," Energy, Elsevier, vol. 239(PC).
    4. Jabir Ali Ouassou & Julian Straus & Marte Fodstad & Gunhild Reigstad & Ove Wolfgang, 2021. "Applying endogenous learning models in energy system optimization," Papers 2106.06373, arXiv.org.
    5. Qureshi, Fazil & Yusuf, Mohammad & Kamyab, Hesam & Vo, Dai-Viet N. & Chelliapan, Shreeshivadasan & Joo, Sang-Woo & Vasseghian, Yasser, 2022. "Latest eco-friendly avenues on hydrogen production towards a circular bioeconomy: Currents challenges, innovative insights, and future perspectives," Renewable and Sustainable Energy Reviews, Elsevier, vol. 168(C).
    6. Christoph Falter & Andreas Sizmann, 2021. "Solar Thermochemical Hydrogen Production in the USA," Sustainability, MDPI, vol. 13(14), pages 1-15, July.
    7. Dingenen, Fons & Verbruggen, Sammy W., 2021. "Tapping hydrogen fuel from the ocean: A review on photocatalytic, photoelectrochemical and electrolytic splitting of seawater," Renewable and Sustainable Energy Reviews, Elsevier, vol. 142(C).
    8. Thomassen, Gwenny & Van Passel, Steven & Dewulf, Jo, 2020. "A review on learning effects in prospective technology assessment," Renewable and Sustainable Energy Reviews, Elsevier, vol. 130(C).
    9. Böhm, Hans & Zauner, Andreas & Rosenfeld, Daniel C. & Tichler, Robert, 2020. "Projecting cost development for future large-scale power-to-gas implementations by scaling effects," Applied Energy, Elsevier, vol. 264(C).
    10. Jabir Ali Ouassou & Julian Straus & Marte Fodstad & Gunhild Reigstad & Ove Wolfgang, 2021. "Applying Endogenous Learning Models in Energy System Optimization," Energies, MDPI, vol. 14(16), pages 1-21, August.

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