Single atoms supported on metal oxides for energy catalysis

Single-atom catalysts (SACs) have attracted wide interest from researchers, as they promisingly bridge the gap between homogeneous and heterogeneous catalysts. There are various types of supports reported to anchor single metal atoms. Among them, metal oxides have received much attention because of their specific and variable properties. In this review, the unique role of typical oxide supports in anchoring isolated metal atoms and participating in catalysis is emphasized. The interactions between metal atoms and oxide supports are clarified, so as to show how to stabilize the atomic metal sites and adjust the geometric and electronic structure of single atoms reasonably. Accordingly, we highlight and summarize the progress made in the synthesis of SACs in recent years, placing special emphasis on preventing isolated metal atoms from migrating or agglomerating. In addition, the modern characterization technologies of SACs are summarized and discussed, which can provide strong evidence on the geometrical structures and electronic states of SACs. Then the applications of SACs supported on metal oxides in energy catalytic reactions are reviewed, such as CO oxidation, the water-gas shift reaction, CH4 conversion, CO2 hydrogenation, oxygen reduction reaction, hydrogen evolution reaction, and CO2 reduction reaction. Finally, the existing problems and development prospects in this field are discussed.

Automated summary

Single-atom catalysts (SACs) have attracted attention as they bridge the gap between homogeneous and heterogeneous catalysts. Metal oxides are commonly used as supports to anchor single metal atoms, with a focus on stabilizing atomic metal sites and adjusting their electronic structure. Progress in SAC synthesis, characterization technologies, and applications in energy catalytic reactions are highlighted, along with discussions on existing challenges and future prospects in the field.