Defective Bimetallic Selenides for Selective CO2 Electroreduction to CO

CO2 electroreduction (CO2RR) to CO is promising for the carbon cycle but still remains challenging. Au is regarded as the most selective catalyst for CO2RR, but its high cost significantly hinders its industrial application. Herein, the bimetallic CuInSe2 is found to exhibit an Au‐like catalytic fea...

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Published in:Advanced materials (Weinheim) 2022-01, Vol.34 (3), p.e2106354-n/a
Main Authors: Wang, Jiajun, Zheng, Xuerong, Wang, Guangjin, Cao, Yanhui, Ding, Wenlong, Zhang, Jinfeng, Wu, Han, Ding, Jia, Hu, Huilin, Han, Xiaopeng, Ma, Tianyi, Deng, Yida, Hu, Wenbin
Format: Article
Language:English
Subjects:
Adsorption
Aqueous electrolytes
band optimization
bimetallic selenides
Bimetals
Carbon cycle
Carbon dioxide
Catalysts
CO 2 electroreduction
Copper indium selenides
Electrocatalysts
Electrowinning
Hydrogen evolution
Industrial applications
Materials science
Noble metals
orbital interaction
Selenides
Selenium
structure–function relationship
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Summary:CO2 electroreduction (CO2RR) to CO is promising for the carbon cycle but still remains challenging. Au is regarded as the most selective catalyst for CO2RR, but its high cost significantly hinders its industrial application. Herein, the bimetallic CuInSe2 is found to exhibit an Au‐like catalytic feature: i) the interaction of Cu and In orbitals induces a moderate adsorption strength of CO2RR intermediates and favors the reaction pathway; and ii) the hydrogen evolution is energetically unfavorable on CuInSe2, as a surface reconstruction along with high energy change will occur after hydrogen adsorption. Furthermore, the Se vacancy is found to induce an electron redistribution, slightly tune the band structure, and optimize the CO2RR route of bimetallic selenide. Consequently, the Se‐defective CuInSe2 (V‐CuInSe2) achieves a highly selective CO production ability that is comparable to noble metals in aqueous electrolyte, and the V‐CuInSe2 cathode shows a satisfactory performance in an aqueous Zn–CO2 cell. This work demonstrates that designing cost‐effective catalysts with noble‐metal‐like properties is an ideal strategy for developing efficient electrocatalysts. Moreover, the class of transition bimetallic selenides has shown promising prospects as active and cost‐effective electrocatalysts owing to their unique structural, electronic, and catalytic properties. Bimetallic CuInSe2 with Se vacanies (V‐CuInSe2) significantly optimizes the adsorption of CO2 electroreduction intermediates owing to its moderate band center relative to the Fermi level. Meanwhile, hydrogen evolution is suppressed on V‐CuInSe2 due to an energetically unfavorable surface reconstruction after hydrogen adsorption. Consequently, the V‐CuInSe2 achieves a highly active and selective CO generation ability.
ISSN:0935-9648
1521-4095
DOI:10.1002/adma.202106354