电解水中的镧系元素

IF 10.7 Q1 CHEMISTRY, PHYSICAL
EcoMat Pub Date : 2024-09-12 DOI:10.1002/eom2.12484
Ashish Gaur, Jatin Sharma, Enkhtuvshin Enkhbayar, Min Su Cho, Jeong Ho Ryu, HyukSu Han
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引用次数: 0

摘要

生产绿色氢气最可行的技术是水电解法。近年来,人们对使用过渡金属化合物作为阳极和阴极的电催化剂进行了大量研究。人们尝试了多种策略来提高其原始结构的电催化活性。其中一种方法是引入稀土金属或与稀土金属化合物形成异质结构。稀土金属的加入使活性显著提高了许多倍,而其化合物则提供了结构稳定性和操纵原始系统电子特性的能力。这些因素导致了最近对稀土金属电催化剂的研究热潮。目前,人们迫切希望能有一篇综述性文章,对科学进展进行全面概述,并阐明镧系元素掺杂的机理影响。本综述首先解释镧系元素的电子结构。接下来,我们将探讨机理方面的问题,然后介绍镧系元素掺杂和异质结构形成在水电解应用中的最新进展。我们希望这一特别的研究工作能使广大读者受益,并激励人们在这一感兴趣的领域开展更多的研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Lanthanides in the water electrolysis

Lanthanides in the water electrolysis

The most feasible technique for producing green hydrogen is water electrolysis. In recent years, there has been significant study conducted on the use of transition metal compounds as electrocatalysts for both anodes and cathodes. Peoples have attempted several strategies to improve the electrocatalytic activity of their original structure. One such technique involves introducing rare earth metals or creating heterostructures with compounds based on rare earth metals. The incorporation of rare earth metals significantly enhances the activity by many folds, while their compounds offer structural stability and the ability to manipulate the electronic properties of the original system. These factors have led to a recent boom in investigations on rare earth metal-based electrocatalysts. There is currently a pressing demand for a review article that can provide a comprehensive overview of the scientific advancements and elucidate the mechanistic aspects of the impact of lanthanide doping. This review begins by explaining the electronic structure of the lanthanides. We next examine the mechanistic aspects, followed by recent advancements in lanthanide doping and heterostructure formation for water electrolysis applications. It is expected that this particular effort will benefit a broad audience and stimulate more research in this area of interest.

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CiteScore
17.30
自引率
0.00%
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