Creating Atomic Ordering in Electrocatalysis

Catalysis always proceeds in a chaotic fashion. Therefore, identifying the working principles of heterogeneous catalysts is a challenging task. Creating atomic order in heterogeneous catalysts simplifies this task and also offers new opportunities for rationally designing active sites to manipulate...

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Veröffentlicht in:	Advanced functional materials 2023-02, Vol.33 (7), p.n/a
Hauptverfasser:	Lin, Chao, Jiang, Zheng, Zhao, Tiejun, Li, Xiaopeng, Luo, Wei, Lee, Jung‐Ho
Format:	Artikel
Sprache:	eng
Schlagworte:	atomic dispersions atomically ordered structures Catalysis Catalysts cation exchange reactions Chemical properties Electrocatalysis Electrocatalysts heterogeneous catalysts Intermetallic compounds Materials science metal atom arrays Principles
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creator	Lin, Chao Jiang, Zheng Zhao, Tiejun Li, Xiaopeng Luo, Wei Lee, Jung‐Ho
description	Catalysis always proceeds in a chaotic fashion. Therefore, identifying the working principles of heterogeneous catalysts is a challenging task. Creating atomic order in heterogeneous catalysts simplifies this task and also offers new opportunities for rationally designing active sites to manipulate catalytic performance. The recent rapid advances in heterogeneous electrocatalysis have led to exciting progress in the construction of atomically ordered materials. Here, the latest progress in electrocatalysts with the periodic atomic arrangement, including intermetallic compounds with long‐range order and metal atom‐array catalysts with short‐range order is summarized. The synthesis principles and the intriguing physical and chemical properties of these electrocatalysts are discussed. Furthermore, the compelling prospects of atomically ordered catalysts in the frontier of catalyst research are outlined. Rationally designing new heterogeneous catalysts with well‐defined atomic features simplifies catalysis research and may deliver novel catalytic properties. This perspective reviews an emerging class of heterogeneous catalysts, named metal atom‐array catalysts (MACs), with tunable interatomic distance and electronic properties, a strong synergy between atoms, and the predictive nature of the atomic arrangement. The synthesis principle and promising development directions of MACs are discussed.
doi_str_mv	10.1002/adfm.202212827
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subjects	atomic dispersions atomically ordered structures Catalysis Catalysts cation exchange reactions Chemical properties Electrocatalysis Electrocatalysts heterogeneous catalysts Intermetallic compounds Materials science metal atom arrays Principles
title	Creating Atomic Ordering in Electrocatalysis
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