True Cost of Solar Hydrogen

Vartiainen, Eero; Breyer, Christian; Moser, David; Román, E.; Busto, Chiara; Masson, G.; Bosch, Elina; Jäger-Waldau, Arnulf

doi:10.1002/solr.202100487

Cited by 77 publications

(65 citation statements)

References 46 publications

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“…Global-local analyses for hybrid PV-wind based green Hydrogen indicates huge and lowcost upcoming Hydrogen potential all over the world [85]. Latest cost-optimized green Hydrogen for large utility-scale applications indicates that there is cost parity of green Hydrogen and SMR H 2 for the best solar resource regions and broad cost parity is expected worldwide by 2030 [86]. Furthermore, electrolyzer cost competitiveness is largely limited by policy obstacles that prevent electrolyzer participation in the wholesale electricity market [87].…”

Section: Statements In the Seibert-rees (S-r) Paper And Counter-argumentsmentioning

confidence: 99%

“…Section 3.1.12, "The Liquid Fuels Question" claims that "it is highly unlikely that synthetic liquid fuel substitutes for FFs [fossil fuels] can be produced sustainably in any more than small quantities for niche applications". Vast literature has been published in recent years on e-fuels and e-chemicals, such as green Hydrogen [85,86,163], e-Methane [164,165], Fischer-Tropsch fuels [166,167], e-Ammonia [168,169] and e-Methanol [170,171], all showing that electricity-based fuels are in reach. In a global energy system transition analysis reaching 100% RE in 2050 [46], with 90% electricity share in primary energy (mainly PV, wind and some hydropower) and strong growth in energy service demands, it has been shown that the total energy system cost can be kept at present levels, while the overall energy system efficiency can be increased by a factor of two [46], mainly due to the phase-out of combustion processes which can be substituted by direct electricity-based processes.…”

Section: Statements In the Seibert-rees (S-r) Paper And Counter-argumentsmentioning

confidence: 99%

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Comment on Seibert, M.K.; Rees, W.E. Through the Eye of a Needle: An Eco-Heterodox Perspective on the Renewable Energy Transition. Energies 2021, 14, 4508

et al. 2022

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This paper exposes the many flaws in the article “Through the Eye of a Needle: An Eco-heterodox Perspective on the Renewable Energy Transition, authored by Siebert and Rees and recently published in Energies as a Review. Our intention in submitting this critique is to expose and rectify the original article’s non-scientific approach to the review process that includes selective (and hence biased) screening of the literature focusing on the challenges related to renewable energies, without discussing any of the well-documented solutions. In so doing, we also provide a rigorous refutation of several statements made by a Seibert–Rees paper, which often appear to be unsubstantiated personal opinions and not based on a balanced review of the available literature.

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Section: Statements In the Seibert-rees (S-r) Paper And Counter-argumentsmentioning

confidence: 99%

Section: Statements In the Seibert-rees (S-r) Paper And Counter-argumentsmentioning

confidence: 99%

Comment on Seibert, M.K.; Rees, W.E. Through the Eye of a Needle: An Eco-Heterodox Perspective on the Renewable Energy Transition. Energies 2021, 14, 4508

et al. 2022

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“…In the literature, various techno‐economic studies of hydrogen production from solar energy can be found. [ 6–12 ] Broadly speaking, they can be classified into three categories: 1.Modelling of state‐of‐the‐art technologies to obtain an estimate for the current LCOH 2 [ 6,11 ] …”

Section: Introductionmentioning

confidence: 99%

“…In the literature, various techno-economic studies of hydrogen production from solar energy can be found. [6][7][8][9][10][11][12] Broadly speaking, they can be classified into three categories:…”

mentioning

confidence: 99%

“…Modelling of hypothetical future technologies to obtain an estimate for a potential future LCOH 2 [13,14] 3. Learning curve analysis based on learning rates to model the decrease of LCOH 2 over time [9,10] Modelling of state-of-the-art or potential future technologies provides valuable single-point cost estimates and also reveals the impact of individual parameters through sensitivity analysis. However, they do not capture the trajectory of technological progress.…”

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confidence: 99%

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How Much Technological Progress is Needed to Make Solar Hydrogen Cost‐Competitive?

Schneidewind

2022

Advanced Energy Materials

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Cost‐effective production of green hydrogen is a major challenge for global adoption of a hydrogen economy. Technologies such as photoelectrochemical (PEC) or photocatalytic (PC) water splitting and photovoltaic + electrolysis (PV+E) allow for sustainable hydrogen production from sunlight and water, but are not yet competitive with fossil fuel‐derived hydrogen. Herein, open‐source software for techno‐economic analysis (pyH2A) along with a Monte Carlo‐based methodology for modelling of technological progress are developed. Together, these tools allow for the study of required technological improvement to reach a competitive target cost. They are applied to PEC, PC, and PV+E to identify required progress for each and derive actionable research targets. For PEC, it is found that cell lifetime improvements (>2 years) and operation under high solar concentration (>50‐fold) are crucial, necessitating systems with high space‐time yields. In the case of PC, solar‐to‐hydrogen efficiency has to reach at least 6%, and lowering catalyst concentration (<0.2 g L−1) by improving absorption properties is identified as a promising path to low‐cost hydrogen. PV+E requires ≈two or threefold capital cost reductions for photovoltaic and electrolyzer components. It is hoped that these insights can inform materials research efforts to improve these technologies in the most impactful ways.

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Direct Seawater Electrolysis: From Catalyst Design to Device Applications

Fei,

Liu,

Liu

et al. 2023

Advanced Materials

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Direct seawater electrolysis (DSE) for hydrogen production, using earth‐abundant seawater as the feedstock and renewable electricity as the driving source, paves a new opportunity for flexible energy conversion/storage and smooths the volatility of renewable energy. Unfortunately, the complex environments of seawater impose significant challenges on the design of DSE catalysts, and the practical performance of many current DSE catalysts remains unsatisfactory on the device level. However, many studies predominantly concentrated on the development of electrocatalysts for DSE without giving due consideration to the specific devices. To mitigate this gap, we systematically evaluated the most recent progress (mainly published within the year 2020–2023) of DSE electrocatalysts and devices. By discussing key bottlenecks, corresponding mitigation strategies, and various device designs and applications, we emphasize that it is tremendously challenging to address the trade‐off among activity, stability, and selectivity for DSE electrocatalysts by a single shot. In addition, the rational design of the DSE electrocatalysts needs to align with the specific device configuration, which is more effective than attempting to comprehensively enhance all catalytic parameters. This work, featuring the first review of this kind to consider rational catalyst design in the framework of DSE devices, will facilitate practical DSE development.This article is protected by copyright. All rights reserved

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True Cost of Solar Hydrogen

Cited by 77 publications

References 46 publications

Comment on Seibert, M.K.; Rees, W.E. Through the Eye of a Needle: An Eco-Heterodox Perspective on the Renewable Energy Transition. Energies 2021, 14, 4508

Comment on Seibert, M.K.; Rees, W.E. Through the Eye of a Needle: An Eco-Heterodox Perspective on the Renewable Energy Transition. Energies 2021, 14, 4508

How Much Technological Progress is Needed to Make Solar Hydrogen Cost‐Competitive?

Direct Seawater Electrolysis: From Catalyst Design to Device Applications

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