Recent progress in understanding the catalyst layer in anion exchange membrane electrolyzers – durability, utilization, and integration

EES catalysis Pub Date : 2023-11-07 DOI:10.1039/D3EY00193H
Emily K. Volk, Melissa E. Kreider, Stephanie Kwon and Shaun M. Alia
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Abstract

Anion exchange membrane water electrolyzers (AEMWEs) are poised to play a key role in reducing capital cost and materials criticality concerns associated with traditional low-temperature electrolysis technologies. To accelerate the development and deployment of this technology, an in-depth understanding of cell materials integration is essential. Notably, the complex chemistries and interactions within the catalyst layer (consisting of the anode/cathode catalyst, anion exchange ionomer, and their interfaces with the transport layers and membrane) collectively influence overall cell performances, lifetimes, and costs. This review outlines recent advances in understanding the catalyst layer in AEMWEs. Specifically, electrode development strategies (including catalyst deposition techniques and configurations as well as transport layer design strategies) and our current understanding of catalyst–ionomer interactions are discussed. Effects of cell assembly and operational variables (including compression, temperature, pressure, and electrolyte conditions) on cell performance are also discussed. Lastly, we consider cutting-edge in situ and ex situ diagnostic techniques to study the complex chemistries within the catalyst layer as well as discuss degradation mechanisms that arise due to the integration of cell components. Simultaneously, comparisons are made to proton exchange membrane water electrolyzers (PEMWEs) and liquid alkaline water electrolyzers (LAWE) throughout the review to provide context to researchers transitioning into the AEMWE space. We also include recommendations for standard operating procedures, configurations, and metrics for comparing activity and stability.

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了解阴离子交换膜电解槽催化剂层的最新进展--耐用性、利用和整合
阴离子交换膜水电解槽(AEMWEs)有望在降低与传统低温电解技术相关的资本成本和材料临界性方面发挥关键作用。要加快这项技术的开发和应用,就必须深入了解电池材料的集成。值得注意的是,催化剂层(由阳极/阴极催化剂、阴离子交换离子膜及其与传输层和膜的界面组成)内复杂的化学性质和相互作用共同影响着电池的整体性能、寿命和成本。本综述概述了在了解 AEMWE 催化剂层方面的最新进展。具体来说,将讨论电极开发策略(包括催化剂沉积技术和配置以及传输层设计策略)以及我们目前对催化剂-离子体相互作用的理解。此外,我们还讨论了电池组装和操作变量(包括压缩、温度、压力和电解质条件)对电池性能的影响。最后,我们考虑采用最先进的原位和非原位诊断技术来研究催化剂层内的复杂化学反应,并讨论由于电池组件的集成而产生的降解机制。与此同时,我们还将质子交换膜水电解槽(PEMWE)和液体碱性水电解槽(LAWE)进行了比较,以便为进入 AEMWE 领域的研究人员提供背景资料。我们还就标准操作程序、配置以及比较活性和稳定性的指标提出了建议。
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