Recent progress in electrochemical reduction of carbon dioxide on metal single‐atom catalysts
Siming Huo, Jessie Lu, Xianqin Wang
Abstract
Abstract Electrochemical reduction reaction of CO 2 (CO 2 RR) is a promising technology for alleviating the global warming caused by the emission of CO 2 . This technology, however, is still in the stage of finding efficient catalysts. The catalysts must be able to convert CO 2 to other carbon‐based products with high activity and selectivity to valuable chemicals. In this review, previous development of heteroatom‐doped metal‐free carbon materials (H‐CMs) is briefly summarized. Recent progress of CO 2 RR promoted by metal single‐atom catalysts (M‐SACs) is then discussed with emphasis on the synthesis of M‐SACs, the catalytic performance, and reaction mechanisms. The high temperature pyrolysis method and electrodeposition are attracting attentions recently to prepare M‐SACs with high metal loading on N‐doped carbon materials, a very active M‐SACs system for the CO 2 RR. Theoretical calculations of free energy change on active sites, the Operando X‐ray absorption near edge structure (XANES), and Bader charge analysis reveal a significant role of metal oxidation state and charge transfer between metal atoms and absorbed CO. The challenges and perspectives for the extensive applications of M‐SACs in CO 2 RR are also discussed in this review.