Rational construction of ZnIn2S4/Co3Se4 with boosted photocatalytic hydrogen production through cooperate with S-scheme heterojunction and photothermal effect

The rational design of excellent visible light photocatalysts that efficiently utilize the solar spectrum is urgently needed. In this work, ZnIn2S4 (ZIS) and Co3Se4 (CS) were coupled by a multistep process involving simple ultrasonic self-assembly and calcination to form ZnIn2S4/Co3Se4 (ZIS/CS) photocatalysts with synergistic S-scheme heterojunctions and photothermal effects, which realized efficient photocatalytic hydrogen (H-2) production with optimal H-2 yield of 2.46 mmol h(-1) g(-1), superior to pure ZIS (0.47 mmol h(-1) g(-1)) by a factor of 5.23. The excellent cyclic stability and wide environmental adaptability to the ionic environment of water of ZIS/CS were proved. The positive impaction of photothermal effect on the H-2 yield of ZIS/CS was investigated and confirmed by the temperature change of photocatalysts powder or photocatalytic system under light irradiation. In addition, based on a series of characterization analyses and first-principle simulation calculations, a charge transfer pathway for ZIS/CS S-scheme heterojunctions was proposed. This work provides valuable ideas and feasible research methods for the design of stable and practical photocatalysts.