Activating inert non-defect sites in Bi catalysts using tensile strain engineering for highly active CO2 electroreduction

Chen, Xingbao; Lu, Ruihu; Li, Chengbo; Luo, Wen; Yu, Ruohan; Zhu, Jiexin; Lv, Lei; Dai, Yuhang; Gong, Shanhe; Zhou, Yazhou; Xiong, Weiwei; Wu, Jiahao; Cai, Hongwei; Wu, Xinfei; Deng, Zhaohui; Xing, Boyu; Su, Lin; Wang, Fei; Chao, Feiyang; Chen, Wei; Xia, Chuan; Wang, Ziyun; Mai, Liqiang

doi:10.1038/s41467-025-56975-8

articleNature CommunicationsFeb 24, 2025GOLD OA

Activating inert non-defect sites in Bi catalysts using tensile strain engineering for highly active CO2 electroreduction

XCXingbao Chen RLRuihu Lu CLChengbo Li WLWen Luo RYRuohan Yu

University of Auckland · Wuhan University of Technology · +4 more institutions

PubMed

Indexed incrossrefdoajpubmed

Abstract

Bi-defect sites are highly effective for CO2 reduction (CO2RR) to formic acid, yet most catalytic surfaces predominantly feature inert, non-defective Bi sites. To overcome this limitation, herein, tensile strain is introduced on wholescale non-defective Bi sites. Under rapid thermal shock, the Bi-based metal-organic framework (Bi-MOF-TS) shows weakened Bi–O bonds and produced tiny Bi clusters. During electrochemical reduction, these clusters create numerous continuous vacancies, inducing weak tensile strain over a large range of surrounding non-defective Bi sites. This strain enhances *OHCO intermediates adsorption and substantially lowers the reaction barrier. As a result, Bi-MOF-TS achieves a faradaic…

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Topics

Keywords

Faraday efficiency
Catalysis
Formate
Electrolyte
Materials science
Inert
Electrochemistry
Formic acid

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