Facile fabrication of Zn3In2S6@SnS2 3D heterostructure for efficient visible-light photocatalytic hydrogen evolution

A series of Zn3In2S6@SnS2 photocatalysts with different SnS2 mass ratios were prepared by hydrothermal method. Two photoactive sulfide materials were prepared into composite materials for photocatalytic hydrogen evolution under visible light excitation. The unique structure accelerates the separation and transfer of photo-generated electrons and holes. Due to its unique composition advantages, the Zn3In2S6@SnS2 three-dimensional heterostructure without any co-catalyst (SnS2 doping amount of 10 %) exhibited remarkable activity, and its hydrogen production rate was 15443 mu mol h- 1g- 1, indicating high photocatalytic stability for water decom-position. Based on photoelectrochemical (PEC) and hydrogen evolution test, a reasonable photocatalytic mechanism was proposed.

Automated summary

A series of Zn3In2S6@SnS2 photocatalysts with different SnS2 mass ratios were prepared by hydrothermal method. The composite materials were used for photocatalytic hydrogen evolution under visible light excitation. The unique structure accelerates the separation and transfer of photo-generated electrons and holes. The Zn3In2S6@SnS2 three-dimensional heterostructure without any co-catalyst (SnS2 doping amount of 10 %) exhibited remarkable activity, and its hydrogen production rate was 15443 mu mol h- 1g- 1, indicating high photocatalytic stability for water decomposition. Based on photoelectrochemical (PEC) and hydrogen evolution tests, a reasonable photocatalytic mechanism was proposed.