Atomically Dispersed Manganese on Carbon Substrate for Aqueous and Aprotic CO2 Electrochemical Reduction

CO2 utilization and conversion are of great importance in alleviating the rising CO2 concentration in the atmosphere. Here, a single‐atom catalyst (SAC) is reported for electrochemical CO2 utilization in both aqueous and aprotic electrolytes. Specifically, atomically dispersed Mn–N4 sites are embedded in bowl‐like mesoporous carbon particles with the functionalization of epoxy groups in the second coordination spheres. Theoretical calculations suggest that the epoxy groups near the Mn–N4 site adjust the electronic structure of the catalyst with reduced reaction energy barriers for the electrocatalytic reduction of CO2 to CO. The resultant Mn‐single‐atom carbon with N and O doped catalyst (MCs‐(N,O)) exhibits extraordinary electrocatalytic performance with a high CO faradaic efficiency of 94.5%, a high CO current density of 13.7 mA cm−2, and a low overpotential of 0.44 V in the aqueous environment. Meanwhile, as a cathode catalyst for aprotic Li–CO2 batteries, the MCs‐(N,O) with well‐regulated active sites and unique mesoporous bowl‐like morphology optimizes the nucleation behavior of discharge products. MCs‐(N,O)‐based batteries deliver a low overpotential and excellent cyclic stability of 1000 h. The findings in this work provide a new avenue to design and fabricate SACs for various electrochemical CO2 utilization systems. Systematically theoretical calculations are performed to seek the optimal structure from atomically dispersed manganese for CO2 electrochemical reduction catalysts. Based on the theoretical results, Mn–N4 sites with the functionalization of epoxy groups in the second coordination spheres are designed and embedded in a bowl‐like mesoporous carbon substrate, which exhibits superior electrochemical performance in both the aqueous and aprotic electrolyte.