Transition metal-nitrogen sites for electrochemical carbon dioxide reduction reaction

Abstract

Electrochemical CO2 reduction reaction (CO2RR) powered by renewable electricity has emerged as the most promising technique for CO2 conversion, making it possible to realize a carbon-neutral cycle. Highly efficient, robust, and cost-effective catalysts are highly demanded for the near-future practical applications of CO2RR. Previous studies on atomically dispersed metal-nitrogen (M-Nx) sites constituted of earth abundant elements with maximum atom-utilization efficiency have demonstrated their performance towards CO2RR. This review summarizes recent advances on a variety of M-Nx sites-containing transition metal-centered macrocyclic complexes, metal organic frameworks, and M-Nx-doped carbon materials for efficient CO2RR, including both experimental and theoretical studies. The roles of metal centers, coordinated ligands, and conductive supports on the intrinsic activity and selectivity, together with the importance of reaction conditions for improved performance are discussed. The mechanisms of CO2RR over these M-Nx-containing materials are presented to provide useful guidance for the rational design of efficient catalysts towards CO2RR.