Light Enhanced Water Dissociation in Bipolar Membranes

IF 3 4区化学 Q3 CHEMISTRY, PHYSICAL

ChemPhotoChem Pub Date : 2025-02-14 DOI:10.1002/cptc.202400377

Patrick K. Giesbrecht, Matthew J. Margeson, Mita Dasog, Michael S. Freund

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Abstract

Bipolar membrane (BPM) integration can allow robust and abundant materials to be implemented into energy conversion frameworks and purification pathways vital for the development of clean technologies. However, large membrane voltages associated with water dissociation (WD) have hampered widespread adoption. This work investigates an alternative method to reduce the overvoltage associated with WD operation by illuminating the BPM interface in the presence of nanoparticulate catalyst layers that exhibit plasmonic character. The plasmonic character of the catalyst enhanced the field locally near the active catalyst site, lowering the resistance associated with WD as well as the onset potential for WD. Optimal catalyst loadings allowed a balance of light absorption, catalyst activity, and field utilization. Composites of known WD catalysts that exhibited minimal light activity with a plasmonic and WD active material exhibited improvements in the WD resistance and overvoltage of up to 20 % upon irradiation. This proof-of-concept work introduces a new paradigm for altering WD activity in BPMs, where the optical activity of WD catalysts can provide further tunability towards efficient WD and alternative energy conversion frameworks.

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光增强双极膜中的水解离

双极膜（BPM）集成可以允许强大和丰富的材料实施到能源转换框架和净化途径对清洁技术的发展至关重要。然而，与水解离（WD）相关的大膜电压阻碍了广泛采用。这项工作研究了一种替代方法，通过在具有等离子体特征的纳米颗粒催化剂层存在的情况下照亮BPM界面，来降低与WD操作相关的过电压。催化剂的等离子体特性增强了活性催化剂部位附近的局部场，降低了与WD相关的电阻以及WD的起始电位。最佳催化剂负载可以平衡光吸收、催化剂活性和现场利用率。已知的具有最小光活性的WD催化剂与等离子体和WD活性材料的复合材料在辐照后的WD电阻和过电压提高高达20%。这项概念验证工作引入了一种改变bpm中WD活性的新范例，其中WD催化剂的光学活性可以为高效WD和替代能源转换框架提供进一步的可调性。

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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来源期刊

ChemPhotoChem Chemistry-Physical and Theoretical Chemistry

CiteScore

5.80

自引率

5.40%

发文量

165

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