Heterostructured core-shell CoS1.097@ZnIn2S4 nanosheets for enhanced photocatalytic hydrogen evolution under visible light

Rational constructing hierarchical core-shell structured photocatalysts to accelerate the separation and transfer of light-induced electrons is extraordinarily indispensable to boost the performance of photocatalytic hydrogen evolution. Herein, we integrate two-dimensional (2D) ZnIn2S4 (ZIS) nanosheets and flower-like CoS1.097 assembled with one-dimensional (1D) nanothorns to construct hierarchical 1D/2D CoS1.097@ZIS with ZIS nanosheets and CoS1.097 nanothorns as shell and core respectively as an effective visible light photocatalyst to produce hydrogen from water splitting. The optimized 8.5-CoS1.097@ZIS photocatalyst demonstrates an outstanding activity with hydrogen production rate of 2632.33 mu mol g- 1h- 1 (6.42 times of ZIS alone) and good stability for photocatalytic water splitting. The enhanced performance can be ascribed to the distinctive structure and composition of CoS1.097@ZIS, which affords intimate contact interface, strong light absorption and abundant reaction sites, thus facilitating the separation and transfer of the charge carriers as well as inhibiting charge recombination. This work offers a prospective approach to construct 1D/2D core-shell ZIS-based photocatalysts for hydrogen production from water splitting.

Automated summary

In this study, a hierarchical core-shell structured photocatalyst consisting of 2D ZnIn2S4 nanosheets and 1D CoS1.097 nanothorns was constructed for efficient visible light-driven hydrogen production. The optimized 8.5-CoS1.097@ZIS photocatalyst exhibited outstanding activity with a hydrogen production rate of 2632.33 mu mol g- 1h- 1 (6.42 times higher than ZIS alone) and good stability for photocatalytic water splitting. The improved performance can be attributed to the unique structure and composition of CoS1.097@ZIS, which facilitates charge separation and transfer, and inhibits charge recombination.