Insights into the mechanism in electrochemical CO2 reduction over single-atom copper alloy catalysts: A DFT study
Tian‐Fu Liu, Guohui Song, Xiaoju Liu, Zhou Chen, Yu Shen, Qi Wang, Zhangquan Peng, Guoxiong Wang
Abstract
Copper single-atom alloy catalysts (M@Cu SAAs) have shown great promise for electrochemical CO 2 reduction reaction (CO 2 RR). However, a clear understanding of the CO 2 RR process on M@Cu SAAs is still lacking. This study uses density functional theoretical (DFT) calculations to obtain a comprehensive mechanism and the origin of activity of M@Cu SAAs. The importance of the adsorption mode of M@Cu is revealed: key intermediates either adsorbed in the adjacent hollow site around Cu atoms (AD mode) or adsorbed directly on the top site of M (SE mode). AD mode generally exhibits finely tuned binding strengths of key intermediates, which significantly enhances the activity of the catalysts. Increasing the coverage of ∗CO on the M@Cu with SE mode leads to relocation of the active site, resulting in improved activity of C 2 products. The insights gained in this work have significant implications for rational design strategy toward efficient CO 2 RR electrocatalysts.