Abstract

Integration of plasmonic metal and cocatalyst with semiconductor is a promising approach to simultaneously optimize the generation, transfer, and consumption of photoinduced charge carriers for high-performance photocatalysis. The photocatalytic activities of the designed hybrid structures are greatly determined by the efficiencies of charge transfer across the interfaces between different components. In this paper, interface design of Ag-BiOCl-PdO_x hybrid photocatalysts is demonstrated based on the choice of suitable BiOCl facets in depositing plasmonic Ag and PdO_x cocatalyst, respectively. It is found that the selective deposition of Ag and PdO_x on BiOCl(110) planes realizes the superior photocatalytic activity in O₂ evolution compared with the samples with other Ag and PdO_x deposition locations. The reason was the superior hole transfer abilities of Ag-(110)BiOCl and BiOCl(110)-PdO_x interfaces in comparison with those of Ag-(001)BiOCl and BiOCl(001)-PdO_x interfaces. Two effects are proposed to contribute to this enhancement: (1) stronger electronic coupling at the BiOCl(110)-based interfaces resulted from the thinner contact barrier layer and (2) the shortest average hole diffuse distance realized by Ag and PdO_x on BiOCl(110) planes. This work represents a step toward the interface design of high-performance photocatalyst through facet engineering.