The role of oxygen defects in metal oxides for CO2 reduction

Abstract

The abuse of fossil fuels release large amount of CO₂, causing intense global warming. Using photoreduction and electroreduction to convert CO₂ into highly valuable fuels such as CO and CH₄ can effectively solve this problem. However, due to the limited activity and selectivity, pristine catalyst materials cannot meet the requirements of practical applications, which means that some modifications to these catalysts are necessary. In this review, a series of research reports on oxygen defect engineering have been introduced. First, the methods of preparing oxygen defects by heat treatment, doping, and photoinduction combined with influencing factors in the preparation are introduced. Subsequently, common characterization methods of oxygen defects including EPR, Raman, XPS, EXAFS, and HRTEM are summarized. Finally, the mechanisms of introducing oxygen defects to improve CO₂ reduction are discussed, and include enhancing light absorption, improving CO₂ adsorption and activation, as well as promoting stability of the reaction intermediates. The summary of research on oxygen defects provides guidance for researchers who focus on CO₂ reduction and accelerate the realization of its industrial applications in the future.