Hierarchical Co 0.85 Se‐CdSe/MoSe 2 /CdSe Sandwich‐Like Heterostructured Cages for Efficient Photocatalytic CO 2 Reduction

Abstract Fabricating efficient photocatalysts with rapid charge carrier separation and high visible light harvesting is an advisable strategy to improve CO 2 reduction performance. Herein, hierarchical Co 0.85 Se‐CdSe/MoSe 2 /CdSe cages with sandwich‐like heterostructure are prepared to act as efficient photocatalysts for CO 2 reduction. In this study, the structure and composition of the final products can be regulated through the cation‐exchange reaction in the presence of ascorbic acid. In the Co 0.85 Se‐CdSe/MoSe 2 /CdSe cages, MoSe 2 nanosheets function as a bridge to integrate Co 0.85 Se‐CdSe and CdSe on both sides of the MoSe 2 nanosheet shell into a sandwich‐like heterostructured catalyst system, which possesses multiple positive merits for photocatalysis, including accelerated transport and separation of photogenerated carriers, improved visible light utilization, and increased catalytic active sites. Thus, the optimized Co 0.85 Se‐CdSe/MoSe 2 /CdSe cages exhibit remarkable visible‐light photocatalytic performance and outstanding stability for CO 2 reduction with a high CO average yield of 15.04 µmol g −1 h −1 and 90.14% selectivity, which are much higher than those of other control samples including single‐component catalysts and binary hybrid catalysts. This study provides a promising way for the design and fabrication of high‐efficiency photocatalysts.