Photocatalytic reduction of Cr(VI) using newly synthesized black phosphorus/ZnO nanocomposites

Removal of high toxic Cr(VI) with solar plays an important role in improving water pollution, but is facing a dilemma of developing excellent photocatalysts with high conversion efficiency and low cost. Different from traditional nano-structuring, this work focuses on the interfacial hybridization by considering the intrinsic difference in bonding interaction. Herein, we intentionally make some layered black phosphorus (BP) sheets with Van der Waals interaction to bond with ZnO surfaces, in which some additional electron channels can be formed by this multilevel atomic hybridization to accelerate carrier transfer and separation. Compared to the pristine ZnO and BP nanosheets, the light absorption and carrier separation efficiency can be sharply enhanced by this particular electronic structure, which makes the Cr reduction performance enhanced about 7.1 times. Our findings suggest a new insight into accelerating Cr(VI) reduction by designing interfacial atom hybridization.

Automated summary

Removal of high toxic Cr(VI) with solar energy is important for water pollution improvement, but developing photocatalysts with high conversion efficiency and low cost is challenging. This study focuses on interfacial hybridization by bonding layered black phosphorus (BP) sheets with ZnO surfaces, which enhances light absorption and carrier separation efficiency. The Cr reduction performance is improved about 7.1 times by this interfacial atom hybridization approach.