Combined anodic and cathodic peroxide production in an undivided carbonate/bicarbonate electrolyte with 144% combined current efficiency

Frontiers in catalysis Pub Date : 2024-05-17 DOI:10.3389/fctls.2024.1353746

Tobias Schanz, Markus Stöckl, Bastien O. Burek, Dirk Holtmann, Jonathan Z. Bloh

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Abstract

In recent years, the electrochemical synthesis of peroxides has attracted renewed interest as a potential environmentally friendly production compared to the established anthraquinone process. In addition, it is possible to produce the peroxides directly on site, eliminating the need for expensive and hazardous transportation and storage. Cathodic production of hydrogen peroxide from oxygen is already quite well developed. Anodic production from water, on the other hand, is still facing significant challenges, despite its historic pioneering role. In this manuscript we show that anodic and cathodic synthesis of peroxides can even be combined to achieve greater than 100% current efficiency (CE) due to the combined effect of both half-reactions. So far, similar devices have always employed different electrolytes for each, which necessitated the use of a membrane and posed contamination risk. However, herein we show that both half-reactions can also employ the same electrolyte. This enables even an undivided cell, omitting the need for the expensive membranes. Despite its simplicity, this setup yielded an outstanding performance with a combined CE of 144%.

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在未分割的碳酸盐/碳酸氢盐电解质中联合生产阳极和阴极过氧化物，联合电流效率达 144

近年来，过氧化物的电化学合成作为一种潜在的环境友好型生产工艺，与已有的蒽醌工艺相比，再次引起了人们的兴趣。此外，过氧化物可以直接在现场生产，无需昂贵而危险的运输和储存。利用氧气进行阴极法生产过氧化氢的技术已经相当成熟。另一方面，从水中阳极制取过氧化氢尽管具有历史性的先驱作用，但仍然面临着巨大的挑战。在本手稿中，我们展示了过氧化物的阳极和阴极合成甚至可以结合使用，由于两种半反应的共同作用，电流效率（CE）甚至可以超过 100%。迄今为止，类似的装置总是各自使用不同的电解质，这就需要使用膜并带来污染风险。然而，我们在本文中展示了两种半反应也可以使用相同的电解质。这样，即使是不分割的电池，也无需使用昂贵的膜。尽管结构简单，但这一装置却能产生出色的性能，综合 CE 值高达 144%。

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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Frontiers in catalysis

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