Cost-effective design of the alkaline electrolyser for enhanced electrochemical performance and reduced electrode degradation

Aman Dhir; Bushra Al-Duri; Daniel Symes; Waldemar Bujalski

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Cost-effective design of the alkaline electrolyser for enhanced electrochemical performance and reduced electrode degradation

机译：具有成本效益的碱性电解槽设计，可增强电化学性能并减少电极降解

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An alkaline electrolyser was developed and characterized. Three different metals, working as the electrode, were analysed using electrochemical methods to determine the best electrochemical performance. The performance of the Stainless Steel (SS316) electrode and the nickel electrode is much better than that of the conventional iron electrode. Degradation analysis of the electrode materials highlighted the need for the material to be durable and resistant to corrosion from an alkaline environment. Through SEM and mass analysis, it is shown that Nickel exhibits the strongest long-term resistance to surface and electrochemical performance degradation, when compared with Mild Steel (Iron) and SS316.

机译：开发并表征了碱性电解槽。使用电化学方法分析了用作电极的三种不同金属，以确定最佳的电化学性能。不锈钢（SS316）电极和镍电极的性能比常规铁电极的性能好得多。电极材料的降解分析突显了对材料的耐用性和耐碱性环境腐蚀的需求。通过SEM和质量分析表明，与低碳钢（Iron）和SS316相比，镍具有最强的长期抗表面性能和电化学性能退化的能力。

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《International journal of low carbon technologies》 |2015年第4期|共8页
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Aman Dhir; Bushra Al-Duri; Daniel Symes; Waldemar Bujalski;
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中图分类环境科学、安全科学;
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Cost-effective design of the alkaline electrolyser for enhanced electrochemical performance and reduced electrode degradation

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