Energy band engineering and interface transfer strategies to optimize photocatalytic hydrogen evolution performance

The design of energy band structures and the construction of composite materials are effective ways to improve photocatalytic activity. Hence, ZnxCd1-xIn2S4/MoS2 composites were first prepared in this work by combining ZnxCd1-xIn2S4 solid solution and MoS2 nanosheets. The solid solution strategy partly avoided the potential conflicts between visible-light absorption and redox capacity through energy band modulation, and MoS2 provided more active sites and facilitated the separation of photogenerated carriers. This reasonable structural design improved the visible-light absorption capacity, achieved the appropriate redox potential, promoted carrier separation and transfer during photocatalysis. As-prepared composites of Zn1/2Cd1/2In2S4/MoS2-18.9% showed excellent photocatalytic hydrogen evolution performance under visible-light illumination, which provided a hydrogen evolution rate of 2255.21 mu mol g(-1) h(-1) with an quantum yield of 19.55% under incident monochromatic light of 420 nm. Zn1/2Cr1/2In2S4/MoS2 composites also displayed long-term stability after five photocatalytic cycles. Finally, the relevant photogenerated charge transfer and catalytic mechanisms of Zn(x)Cd(1-x)In(2)S(4 )and Zn1/2Cd1/2In2S4/MoS2 composites were proposed and analyzed.

Automated summary

Designing energy band structures and constructing composite materials are effective methods for enhancing photocatalytic activity. By combining ZnxCd1-xIn2S4 solid solution and MoS2 nanosheets, the composite material achieved improved visible-light absorption, appropriate redox potential, enhanced carrier separation, and facilitated carrier transfer during photocatalysis.