Copper vacancy activated plasmonic Cu3-xSnS4 for highly efficient photocatalytic hydrogen generation: Broad solar absorption, efficient charge separation and decreased HER overpotential

Broad absorption spectra with efficient generation and separation of available charge carriers are indispensable requirements for promising semiconductor-based photocatalysts to achieve the ultimate goal of solar-to-fuel conversion. Here, Cu3-xSnS4 (x = 0-0.8) with copper vacancies have been prepared and fabricated via solvothermal process. The obtained copper vacancy materials have extended light absorption from ultraviolet to near-infrared-II region for its significant plasmonic effects. Time-resolved photoluminescence shows that the vacancies can simultaneously optimize charge carrier dynamics to boost the generation of long-lived active electrons for photocatalytic reduction. Density functional theory calculations and electrochemical characterizations further revealed that copper vacancies in Cu3-xSnS4 tend to enhance hydrogen's adsorption energy with an obvious decrease in its H-2 evolution reaction (HER) overpotential. Furthermore, without any loadings, the H-2 production rate was measured to be 9.5 mmol.h(-1).g(-1). The apparent quantum yield was measured to be 27% for wavelength lambda > 380 nm. The solar energy conversion efficiency was measured to be 6.5% under visible-near infrared (vis-NIR) (lambda > 420 nm).