Cu–Mg Dual Single‐Atom Catalysts with CO Spillover for Efficient CO <sub>2</sub> Electroreduction to CH <sub>4</sub>
Peng Zhao, Jing Ai, Hao Jiang, Shaowei Yang, Haidong Shen, Jiarui Zhang, Ying Guo, Qiuyu Zhang, Hepeng Zhang
Abstract
Abstract Selective electroreduction of CO 2 (CO 2 RR) to CH 4 remains a significant challenge due to the complex multi‐electron transfer process and competing C─C coupling pathways. Here, a Cu–Mg dual single‐atom catalyst (CuN 2 –MgN 2 ), which enables a spatially confined CO spillover mechanism was constructed. Spectroscopic characterization and density functional theory calculations confirmed that the atomically dispersed Mg sites not only modulate the electronic structure of Cu sites to lower the overall energy barrier of the CO 2 RR to CH 4 , but also efficiently activate CO 2 to form *CO intermediates, which subsequently migrate to adjacent Cu sites to further hydrogenate into CH 4 . Leveraging these dual advantages, the optimized CuN 2 –MgN 2 electrocatalyst achieved a CH 4 Faradaic efficiency of 78.3% and a partial current density of 228.7 mA cm −2 at−1.1 V versus RHE under ambient CO 2 conditions, with the Turnover frequency of CH 4 on Cu single sites reaching up to 1.72 s −1 , dramatically outperforming currently reported catalysts. This work not only reveals the dynamic regulation mechanism of intermediates during CO 2 ‐to‐CH 4 conversion at the atomic scale but also establishes a universal theoretical model for designing industrial‐grade electrocatalysts with well‐defined active site configurations.