Boosting Electrochemical Reduction of CO<sub>2</sub> to Formate over Oxygen Vacancy Stabilized Copper–Tin Dual Single Atoms Catalysts
Haihua Wang, Ning Wen, Yuqing Wang, Xiuling Jiao, Yuguo Xia, Dairong Chen
Abstract
Abstract Designing reasonable atomic structures is essential in modulating the selectivity of the valuable products produced in the electrochemical CO 2 reduction. Herein, a CuSn diatomic sites electrocatalyst stabilized by double oxygen vacancies on CeO 2‐x is constructed, which exhibits superior electrochemical selectivity toward formate, achieving a 90.0% Faradaic efficiency at formate partial current density of 216.8 mA cm −2 with the applied bias of −1.2 V versus REH. The experimental characterizations and theoretical calculations highlight the significance of the synergistic effect of Cu and Sn diatoms on reducing the activation energy and promoting the formation of intermediate * OCHO, which accounts for its high selectivity toward formate. Meanwhile, the oxygen vacancies on the CeO 2‐x also play a pivotal role in manipulating the electrochemical performance and stability, which underlines the importance of regulating the electronic metal‐support interaction between CuSn diatoms and CeO 2‐x . This work demonstrates an effective method to design efficient electrochemical CO 2 reduction catalysts by modulating the surface structures of single‐atoms anchored support.