通过太阳能热水玻璃高效制氢的最新回顾与展望

IF 5.4 3区工程技术 Q2 ENERGY & FUELS

Wiley Interdisciplinary Reviews-Energy and Environment Pub Date : 2024-07-30 DOI:10.1002/wene.528

Justin T. Tran, Kent J. Warren, Steven A. Wilson, Christopher L. Muhich, Charles B. Musgrave, Alan W. Weimer

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引用次数: 0

摘要

太阳热能水分裂（STWS）利用集中的太阳光从水中产生可再生（或绿色）氢气。由于太阳能热分水利用整个太阳光谱的能量来驱动分水的还原-氧化（氧化还原）反应，因此理论上可以达到很高的太阳能制氢效率。在 STWS 两步法中，首先用集中的太阳光将作为氧化还原媒介的金属氧化物加热到高温（1000°C），使其还原并产生氧气。第二步，将还原材料置于蒸汽中，使其重新氧化为原始氧化状态并产生氢气。本研究全面回顾了这一过程的各个方面，包括迄今为止所考虑的活性材料的还原和氧化化学性质、为促进 STWS 反应而开发的太阳能反应器，以及操作条件对效率的影响（包括最近创新的氧化剂压力升高）。最后，对 STWS 的未来优化进行了展望：可持续能源> 太阳能新兴技术> 氢气和燃料电池新兴技术> 新型燃料

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An updated review and perspective on efficient hydrogen generation via solar thermal water splitting

Solar thermal water splitting (STWS) produces renewable (or green) hydrogen from water using concentrated sunlight. Because STWS utilizes energy from the entire solar spectrum to drive the reduction–oxidation (redox) reactions that split water, it can achieve high theoretical solar‐to‐hydrogen efficiencies. In a two‐step STWS process, a metal oxide that serves as a redox mediator is first heated with concentrated sunlight to high temperatures (T >1000°C) to reduce it and evolve oxygen. In the second step, the reduced material is exposed to steam to reoxidize it to its original oxidation state and produce hydrogen. Various aspects of this process are comprehensively reviewed in this work, including the reduction and oxidation chemistries of active materials considered to date, the solar reactors developed to facilitate the STWS reactions, and the effects of operating conditions—including the recent innovation of elevated oxidant pressure—on efficiency. To conclude the review, a perspective on the future optimization of STWS is provided.This article is categorized under:

Sustainable Energy > Solar Energy

Emerging Technologies > Hydrogen and Fuel Cells

Emerging Technologies > New Fuels

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来源期刊

Wiley Interdisciplinary Reviews-Energy and Environment ENERGY & FUELS-

CiteScore

11.70

自引率

3.30%

发文量

期刊介绍： Wiley Interdisciplinary Reviews: Energy and Environmentis a new type of review journal covering all aspects of energy technology, security and environmental impact. Energy is one of the most critical resources for the welfare and prosperity of society. It also causes adverse environmental and societal effects, notably climate change which is the severest global problem in the modern age. Finding satisfactory solutions to the challenges ahead will need a linking of energy technology innovations, security, energy poverty, and environmental and climate impacts. The broad scope of energy issues demands collaboration between different disciplines of science and technology, and strong interaction between engineering, physical and life scientists, economists, sociologists and policy-makers.