双极膜中先进水电离催化剂的材料描述符

Materials descriptors for advanced water dissociation catalysts in bipolar membranes.

作者信息

Sasmal Sayantan, Chen Lihaokun, Sarma Prasad V, Vulpin Olivia T, Simons Casey R, Wells Kacie M, Spontak Richard J, Boettcher Shannon W

机构信息

Department of Chemistry & Biochemistry and the Oregon Center for Electrochemistry, University of Oregon, Eugene, OR, USA.

Department of Chemical & Biomolecular Engineering and Department of Chemistry, University of California, Berkeley, CA, USA.

出版信息

Nat Mater. 2024 Oct;23(10):1421-1427. doi: 10.1038/s41563-024-01943-8. Epub 2024 Jul 1.

DOI:10.1038/s41563-024-01943-8

PMID:38951650

Abstract

The voltage penalty driving water dissociation (WD) at high current density is a major obstacle in the commercialization of bipolar membrane (BPM) technology for energy devices. Here we show that three materials descriptors, that is, electrical conductivity, microscopic surface area and (nominal) surface-hydroxyl coverage, effectively control the kinetics of WD in BPMs. Using these descriptors and optimizing mass loading, we design new earth-abundant WD catalysts based on nanoparticle SnO synthesized at low temperature with high conductivity and hydroxyl coverage. These catalysts exhibit exceptional performance in a BPM electrolyser with low WD overvoltage (η) of 100 ± 20 mV at 1.0 A cm. The new catalyst works equivalently well with hydrocarbon proton-exchange layers as it does with fluorocarbon-based Nafion, thus providing pathways to commercializing advanced BPMs for a broad array of electrolysis, fuel-cell and electrodialysis applications.

摘要

在高电流密度下驱动水电离（WD）的电压损失是用于能量装置的双极膜（BPM）技术商业化的主要障碍。在此，我们表明，电导率、微观表面积和（标称）表面羟基覆盖率这三个材料描述符可有效控制BPM中WD的动力学。利用这些描述符并优化质量负载，我们基于低温合成的具有高电导率和羟基覆盖率的纳米颗粒SnO设计了新型储量丰富的WD催化剂。这些催化剂在BPM电解槽中表现出优异的性能，在1.0 A/cm²时具有100±20 mV的低WD过电压（η）。这种新型催化剂与基于碳氢化合物的质子交换层配合使用时，效果与基于氟碳的Nafion相当，从而为将先进的BPM商业化以用于广泛的电解、燃料电池和电渗析应用提供了途径。

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双极膜中先进水电离催化剂的材料描述符

Materials descriptors for advanced water dissociation catalysts in bipolar membranes.

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