Harnessing single-atom catalysts for CO2 electroreduction: a review of recent advances

Abstract

Electrochemical CO₂ reduction is an effective pathway to convert CO₂ into valuable fuels and chemicals, which provides a potential alternative to fossil fuel resources and plays a notable role in mitigating environmental issues and energy crises. The feasibility of the CO₂ reduction reaction (CO₂RR) hinges on the development of catalysts that feature high activity, selectivity, and stability. As a new research frontier, single-atom catalysts (SACs) have shown immense potential in the field of CO₂ reduction by virtue of their unique geometric/electronic structures, and have also provided new opportunities for atomic-level understanding of structure–function relationships. Therefore, this review aims to outline recent advances of SACs for CO₂RR. We start by introducing the current research status and general synthesis strategies of SACs, and then shift our focus to analyzing the various regulation strategies and deciphering the structure–function relationships of SACs in the CO₂RR. Finally, we propose future directions and opportunities for CO₂RR-oriented SACs, while also highlighting potential challenges that may be encountered along the way.