Advanced membrane-based electrode engineering toward efficient and durable water electrolysis and cost-effective seawater electrolysis in membrane electrolyzers

Jiayi Tang, Chao Su, Zongping Shao
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Abstract

Researchers have been seeking for the most technically-economical water electrolysis technology for entering the next-stage of industrial amplification for large-scale green hydrogen production. Various membrane-based electrolyzers have been developed to improve electric-efficiency, reduce the use of precious metals, enhance stability, and possibly realize direct seawater electrolysis. While electrode engineering is the key to approaching these goals by bridging the gap between catalysts design and electrolyzers development, nevertheless, as an emerging field, has not yet been systematically analyzed. Herein, this review is organized to comprehensively discuss the recent progresses of electrode engineering that have been made toward advanced membrane-based electrolyzers. For the commercialized or near-commercialized membrane electrolyzer technologies, the electrode material design principles are interpreted and the interface engineering that have been put forward to improve catalytic sites utilization and reduce precious metal loading is summarized. Given the pressing issues of electrolyzer cost reduction and efficiency improvement, the electrode structure engineering toward applying precious metal free electrocatalysts is highlighted and sufficient accessible sites within the thick catalyst layers with rational electrode architectures and effective ions/mass transport interfaces are enabled. In addition, this review also discusses the innovative ways as proposed to break the barriers of current membrane electrolyzers, including the adjustments of electrode reaction environment, and the feasible cell-voltage-breakdown strategies for durable direct seawater electrolysis. Hopefully, this review may provide insightful information of membrane-based electrode engineering and inspire the future development of advanced membrane electrolyzer technologies for cost-effective green hydrogen production.

Abstract Image

在膜电解槽中进行先进的膜电极工程,以实现高效耐用的水电解和经济高效的海水电解
研究人员一直在寻找技术上最经济的水电解技术,以便进入下一阶段的工业放大,实现大规模绿色制氢。为了提高电解效率、减少贵金属的使用、增强稳定性,并在可能的情况下实现直接海水电解,人们开发了各种基于膜的电解器。电极工程是实现这些目标的关键,它在催化剂设计和电解槽开发之间架起了一座桥梁,但作为一个新兴领域,电极工程尚未得到系统分析。在此,本综述将全面讨论电极工程最近在先进膜基电解槽方面取得的进展。针对已商业化或接近商业化的膜电解槽技术,对电极材料设计原理进行了解读,并总结了为提高催化位点利用率和减少贵金属负载而提出的界面工程。考虑到降低电解槽成本和提高效率的迫切问题,本综述强调了应用无贵金属电催化剂的电极结构工程,并通过合理的电极结构和有效的离子/质量传输界面,在厚催化剂层中实现足够的可访问位点。此外,这篇综述还讨论了打破当前膜电解器障碍的创新方法,包括电极反应环境的调整,以及持久直接电解海水的可行电池电压分解策略。希望这篇综述能为基于膜的电极工程提供有见地的信息,并激励未来先进膜电解槽技术的发展,以实现具有成本效益的绿色制氢。
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CiteScore
17.20
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