High-Throughput Screening of Selective Bimetallic Atomic Catalysts for Self-Adaptive Matched Electrochemical Reduction

Due to the impediments of spatial and temporal resolution, the comprehension of microdynamic processes still remains limited, which seriously hinders the advancement of catalyst regulating and the expansion of application. Herein, the efficient selective bimetallic atomic electrode interface was cul...

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Bibliographic Details
Published in:Nano letters 2025-02
Main Authors: Song, Zong-Yin, Li, Pei-Hua, Li, Yong-Yu, Yang, Meng, Lin, Jing-Yi, Xiong, Bo-Ping, Xia, Rui-Ze, Cai, Xin, Duan, Wanchun, Chen, Shi-Hua, Li, Lina, Liu, Wen-Qing, Huang, Xing-Jiu
Format: Article
Language:English
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Summary:Due to the impediments of spatial and temporal resolution, the comprehension of microdynamic processes still remains limited, which seriously hinders the advancement of catalyst regulating and the expansion of application. Herein, the efficient selective bimetallic atomic electrode interface was cultivated via high-throughput screening, achieving self-adaptive parallel electrochemical reduction of Cu(II) and As(III). Combined X-ray absorption fine structure (XAFS) spectroscopy and coordination field theory verified the Ni-Cu specific energy level matching promoted by permitted transition and also reproduced the microscopic dynamic reduction process. Additionally, it was discovered that the Fe-As specific bonding and energy barrier of the smallest potential-determining step (1.40 eV) were derived from the linear shift of the main and peaks of the key arsenic intermediates to the high-energy orbital. This work offers insights into transient reaction dynamics by methods and theoretical simulations, which broadens the design of multisite atomic catalysts.
ISSN:1530-6992
1530-6992
DOI:10.1021/acs.nanolett.4c06524