Interface Engineering of CoS/CdInS Ohmic Junction for Efficient Photocatalytic H Evolution Under Visible Light

The design and development of high-performance photocatalysts from three aspects of simultaneous enhancement of light harvest, carrier migration rate, and redox reaction rate is still a great challenge. Herein, a novel CoS/CdInS ohmic junction with a robust internal electric field (IEF) is successfully prepared via hydrothermal and in situ synthesis methods and is used for effective photocatalytic H evolution (PHE). Under simulated visible light irradiation, the PHE rate of 5% CoS/CdInS can reach 1083.6 μmol h g, which is 6.4 times higher than that of CdInS (170.5 μmol h g). The enhanced PHE performance is mainly ascribed to the improved light harvest and carrier separation efficiency and fast surface H evolution kinetics. Moreover, CoS nanotubes serve as promising Co-based cocatalysts that can evidently enhance PHE activity. Additionally, CoS/CdInS shows superior stability because the photogenerated carrier transfer path restrains the photocorrosion behavior. The photocatalytic mechanism is proposed based on experimental results and DFT calculations. This work offers new insights for the design and development of highly active photocatalysts from interface engineering.