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JOURNAL ARTICLE

Confining High-Valence Iridium Single Sites onto Nickel Oxyhydroxide for Robust Oxygen Evolution

Qun HeSicong QiaoQuan ZhouYuzhu ZhouHongwei ShouPengjun ZhangWenjie XuDaobin LiuShuangming ChenXiaojun WuLi Song

Year: 2022 Journal:   Nano Letters Vol: 22 (9)Pages: 3832-3839   Publisher: American Chemical Society
DOI: 10.1021/acs.nanolett.2c01124
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Abstract

Enhancing activity and stability of iridium- (Ir-) based oxygen evolution reaction (OER) catalysts is of great significance in practice. Here, we report a vacancy-rich nickel hydroxide stabilized Ir single-atom catalyst (Ir1-Ni(OH)2), which achieves long-term OER stability over 260 h and much higher mass activity than commercial IrO2 in alkaline media. In situ X-ray absorption spectroscopy analysis certifies the obvious structure reconstruction of catalyst in OER. As a result, an active structure in which high-valence and peripheral oxygen ligands-rich Ir sites are confined onto the nickel oxyhydroxide surface is formed. In addition, the precise introduction of atomized Ir not only surmounts the large-range dissolution and agglomeration of Ir but also suppresses the dissolution of substrate in OER. Theoretical calculations further account for the activation of Ir single atoms and the promotion of oxygen generation by high-valence Ir, and they reveal that the deprotonation process of adsorbed OH is rate-determining.

Keywords:
Iridium Catalysis Nickel Hydroxide Oxygen evolution Chemistry Deprotonation Dissolution Valence (chemistry) Oxygen Tin Adsorption Desorption Inorganic chemistry Photochemistry Physical chemistry Electrochemistry Ion

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Citation History

Topics

Electrocatalysts for Energy Conversion
Physical Sciences →  Energy →  Renewable Energy, Sustainability and the Environment
Catalytic Processes in Materials Science
Physical Sciences →  Materials Science →  Materials Chemistry
Fuel Cells and Related Materials
Physical Sciences →  Engineering →  Electrical and Electronic Engineering

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