Modulating Electronic Correlations in Ruthenium Oxides for Highly Efficient Oxygen Evolution Reaction.

Precision Chemistry Pub Date : 2024-11-22 eCollection Date: 2025-02-24 DOI:10.1021/prechem.4c00068

Xianbing Miao, Jingda Zhang, Zhenpeng Hu, Shiming Zhou

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引用次数: 0

Abstract

Elucidating the electronic factors dominating the adsorption properties of transition-metal oxides is essential to construct highly efficient oxygen-evolving catalysts for hydrogen production by water splitting but remains a great challenge. Electron correlation from on-site Coulomb repulsion (U) among d-electrons is generally believed to significantly affect the electronic structure of these materials; however, it has long been neglected in studying their adsorption properties. Here, by choosing ruthenium oxide as a model system, we demonstrate the role of electron correlation on the electrocatalytic activity toward oxygen evolution reaction (OER). Our density functional theory plus U calculations on rutile RuO₂ reveal that the electron correlation can tune the adsorption energies for oxygenated intermediate and optimize them after the metallic oxide being a Mott insulator upon increasing U. By regulating the RuO₆ octahedral network, we constructed and synthesized a series of strongly correlated ruthenium oxides, where the Mott insulating ones indeed exhibit a superior OER performance to the metallic RuO₂. Our work builds a bridge between the electrochemistry and Mott physics for transition-metal oxides, opening a new avenue for designing advanced catalysts.

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调节钌氧化物中的电子关联，实现高效氧气进化反应。

阐明主导过渡金属氧化物吸附性能的电子因素对于构建高效的水裂解制氢出氧催化剂至关重要，但仍是一个巨大的挑战。d电子之间的库仑斥力(U)的电子相关性通常被认为对这些材料的电子结构有显著影响；但长期以来，对其吸附性能的研究被忽视。本文选择氧化钌作为模型体系，研究了电子相关对析氧反应（OER）电催化活性的影响。我们的密度泛函理论和对金红石RuO2的U计算表明，随着U的增加，金属氧化物成为Mott绝缘体后，电子相关可以调节含氧中间体的吸附能并优化它们。通过调节RuO6八面体网络，我们构建并合成了一系列强相关的钌氧化物，其中Mott绝缘体确实表现出优于金属RuO2的OER性能。我们的工作在过渡金属氧化物的电化学和莫特物理学之间架起了一座桥梁，为设计先进的催化剂开辟了一条新的途径。

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

Precision Chemistry 精密化学技术-

CiteScore

0.80

自引率

0.00%

发文量

期刊介绍： Chemical research focused on precision enables more controllable predictable and accurate outcomes which in turn drive innovation in measurement science sustainable materials information materials personalized medicines energy environmental science and countless other fields requiring chemical insights.Precision Chemistry provides a unique and highly focused publishing venue for fundamental applied and interdisciplinary research aiming to achieve precision calculation design synthesis manipulation measurement and manufacturing. It is committed to bringing together researchers from across the chemical sciences and the related scientific areas to showcase original research and critical reviews of exceptional quality significance and interest to the broad chemistry and scientific community.