用于质子交换膜水电解的钨酸钴中的水-氢氧化物捕获

Water-hydroxide trapping in cobalt tungstate for proton exchange membrane water electrolysis.

作者信息

Ram Ranit, Xia Lu, Benzidi Hind, Guha Anku, Golovanova Viktoria, Garzón Manjón Alba, Llorens Rauret David, Sanz Berman Pol, Dimitropoulos Marinos, Mundet Bernat, Pastor Ernest, Celorrio Veronica, Mesa Camilo A, Das Aparna M, Pinilla-Sánchez Adrián, Giménez Sixto, Arbiol Jordi, López Núria, García de Arquer F Pelayo

机构信息

ICFO - Institut de Ciències Fotòniques, The Barcelona Institute of Science and Technology, 08860 Castelldefels, Barcelona, Spain.

ICIQ-CERCA - Institute of Chemical Research of Catalonia, The Barcelona Institute of Science and Technology, 43007 Tarragona, Spain.

出版信息

Science. 2024 Jun 21;384(6702):1373-1380. doi: 10.1126/science.adk9849. Epub 2024 Jun 20.

DOI:10.1126/science.adk9849

PMID:38900890

Abstract

The oxygen evolution reaction is the bottleneck to energy-efficient water-based electrolysis for the production of hydrogen and other solar fuels. In proton exchange membrane water electrolysis (PEMWE), precious metals have generally been necessary for the stable catalysis of this reaction. In this work, we report that delamination of cobalt tungstate enables high activity and durability through the stabilization of oxide and water-hydroxide networks of the lattice defects in acid. The resulting catalysts achieve lower overpotentials, a current density of 1.8 amperes per square centimeter at 2 volts, and stable operation up to 1 ampere per square centimeter in a PEMWE system at industrial conditions (80°C) at 1.77 volts; a threefold improvement in activity; and stable operation at 1 ampere per square centimeter over the course of 600 hours.

摘要

析氧反应是通过高效水电解生产氢气及其他太阳能燃料的瓶颈。在质子交换膜水电解（PEMWE）中，通常需要贵金属来稳定催化此反应。在本工作中，我们报告了钨酸钴的分层通过稳定酸性条件下晶格缺陷处的氧化物和水 - 氢氧化物网络，实现了高活性和耐久性。所得催化剂在工业条件（80°C）下的PEMWE系统中，在1.77伏时具有更低的过电位、2伏时每平方厘米1.8安培的电流密度以及高达每平方厘米1安培的稳定运行能力；活性提高了三倍；并且在600小时内每平方厘米1安培的电流下稳定运行。

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用于质子交换膜水电解的钨酸钴中的水-氢氧化物捕获

Water-hydroxide trapping in cobalt tungstate for proton exchange membrane water electrolysis.

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