Selectivity Study of Anodic Seawater Electrolysis Catalysts Using the Rotating Ring-Disc Electrode Method

ECS Transactions Pub Date : 2024-05-17 DOI:10.1149/11309.0003ecst

Oliver Horner, Elod Lajos Gyenge, David P. Wilkinson

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Abstract

Seawater Electrolysis is an exciting alternative to freshwater electrolysis; however, it suffers from a multitude of issues that must be resolved before the technology can be scaled. Corrosive hypochlorite forms at the anode of seawater electrolysis and can damage catalysts and electrolyzer components. Hypochlorite is unstable and can decay, particularly when exposed to heat and metal ions, which can lead to erroneously high oxygen evolution reaction (OER) selectivity conclusions, resulting in poor catalyst and electrolyzer component selection. In this study, we use the rotating ring-disc electrode technique to characterize the selectivity of IrO2, NiO, Co3O4, RuO2, Pt and PtRu electrocatalysts in situ at near-neutral pH (8.4) with linear scan voltammetry (LSV), potentiostatic and galvanostatic experiments. Our findings reveal that elevated temperatures are conducive to higher OER selectivity. Furthermore, when we increased the chloride concentration in the electrolyte with an IrO2 catalyst, we observed that although the overall selectivity towards the OER reaction decreased, the OER current independently increased, indicating a synergistic relationship.

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使用旋转环盘电极法研究阳极海水电解催化剂的选择性

海水电解法是淡水电解法的一种令人兴奋的替代方法；然而，它存在许多问题，必须在该技术规模化之前加以解决。海水电解的阳极会形成腐蚀性次氯酸盐，并可能损坏催化剂和电解槽组件。次氯酸盐不稳定，会发生衰变，尤其是在受热和接触金属离子时，这会导致氧进化反应（OER）选择性结论错误地偏高，从而导致催化剂和电解槽组件选择不当。在本研究中，我们使用旋转环盘电极技术，通过线性扫描伏安法 (LSV)、恒电位和恒电流实验，对 IrO2、NiO、Co3O4、RuO2、Pt 和 PtRu 电催化剂在接近中性 pH 值（8.4）下的选择性进行了原位表征。我们的研究结果表明，温度升高有利于提高 OER 的选择性。此外，当我们用二氧化铱催化剂增加电解液中的氯浓度时，我们观察到虽然对 OER 反应的总体选择性降低了，但 OER 电流却独立地增加了，这表明了一种协同关系。

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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ECS Transactions

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