Performance Losses and Current-Driven Recovery from Cation Contaminants in PEM Water Electrolysis

Elliot Padgett, Anthony Adesso, Haoran Yu, J. Wrubel, Guido Bender, B. Pivovar, S. Alia
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Abstract

Water contaminants are a common cause of failure for polymer electrolyte membrane (PEM) electrolyzers in the field as well as a confounding factor in research on cell performance and durability. In this study, we investigated the performance impacts of feed water containing representative tap water cations at concentrations ranging from 0.5 – 500 μM, with conductivities spanning from ASTM Type II to tap-water levels. We present multiple diagnostic signatures to help identify the presence of contaminants in PEM electrolysis cells. Through analysis of polarization curves and impedance spectroscopy to understand the origins of performance losses, we found that a switch from the acidic to alkaline hydrogen evolution mechanism is a key factor in contaminated cell behavior. Finally, we demonstrated that this mechanism switching can be harnessed to remove cation contaminants and recover cell performance without the use of an acid wash. We demonstrated near-complete recovery of cells contaminated with sodium and calcium, and partial recovery of a cell contaminated with iron, which was further investigated by post-mortem microscopy. The improved understanding of contaminant impacts from this work can inform development of strategies to mitigate or recover performance losses as well as improve the consistency and rigor of electrolysis research.
PEM 水电解中的性能损失和电流驱动的阳离子污染物回收
水污染是聚合物电解质膜(PEM)电解槽在现场发生故障的常见原因,也是电池性能和耐用性研究中的一个干扰因素。在这项研究中,我们调查了含有代表性自来水阳离子的进水对性能的影响,其浓度范围为 0.5 - 500 μM,电导率从 ASTM II 型到自来水水平不等。我们提出了多种诊断特征,以帮助识别 PEM 电解槽中是否存在污染物。通过分析极化曲线和阻抗光谱来了解性能损失的根源,我们发现从酸性氢进化机制到碱性氢进化机制的转换是电池受污染行为的关键因素。最后,我们证明可以利用这种机制转换来去除阳离子污染物,并在不使用酸洗的情况下恢复电池性能。我们展示了被钠和钙污染的细胞几乎完全恢复,以及被铁污染的细胞的部分恢复。通过这项工作,我们加深了对污染物影响的理解,为制定减轻或恢复性能损失的策略提供了依据,并提高了电解研究的一致性和严谨性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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