Electrochemical CO2 Reduction on Cu: Synthesis-Controlled Structure Preference and Selectivity

The electrochemical CO2 reduction reaction (ECO2RR) on Cu catalysts affords high-value-added products and is therefore of great practical significance. The outcome and kinetics of ECO2RR remain insufficient, requiring essentially the optimized structure design for the employed Cu catalyst, and also the fine synthesis controls. Herein, synthesis-controlled structure preferences and the modulation of intermediate's interactions are considered to provide synthesis-related insights on the design of Cu catalysts for selective ECO2RR. First, the origin of ECO2RR intermediate-dominated selectivity is described. Advanced structural engineering approaches, involving alloy/compound formation, doping/defect introduction, and the use of specific crystal facets/amorphization, heterostructures, single-atom catalysts, surface modification, and nano-/microstructures, are then reviewed. In particular, these structural engineering approaches are discussed in association with diversified synthesis controls, and the modulation of intermediate generation, adsorption, reaction, and additional effects. The results pertaining to synthetic methodology-controlled structural preferences and the correspondingly motivated selectivity are further summarized. Finally, the current opportunities and challenges of Cu catalyst fabrication for highly selective ECO2RR are discussed.

Automated summary

This study focuses on the synthesis-controlled structure preferences and the modulation of intermediates' interactions for the design of Cu catalysts for selective ECO2RR. Various advanced structural engineering approaches, including alloy/compound formation, doping/defect introduction, and specific crystal facets/amorphization, are discussed in relation to diverse synthesis controls for achieving highly selective ECO2RR. Challenges and opportunities in Cu catalyst fabrication for ECO2RR are also addressed.