摘要:SummaryPhotocatalytic transformation of biomass into value-added chemicals coupled with co-production of hydrogen provides an explicit route to trap sunlight into the chemical bonds. Here, we demonstrate a rational design of Zn1-xCdxS solid solution homojunction photocatalyst with a pseudo-periodic cubic zinc blende (ZB) and hexagonal wurtzite (WZ) structure for efficient glucose conversion to simultaneously produce hydrogen and lactic acid. The optimized Zn0.6Cd0.4S catalyst consists of a twinning superlattice, has a tuned bandgap, and displays excellent efficiency with respect to hydrogen generation (690 ± 27.6 μmol·h−1·gcat.−1), glucose conversion (~90%), and lactic acid selectivity (~87%) without any co-catalyst under visible light irradiation. The periodic WZ/ZB phase in twinning superlattice facilitates better charge separation, while superoxide radical (⋅O2-) and photogenerated holes drive the glucose transformation and water oxidation reactions, respectively. This work demonstrates that rational photocatalyst design could realize an efficient and concomitant production of hydrogen and value-added chemicals from glucose photocatalysis.Graphical AbstractDisplay OmittedHighlights•Zn1-xCdxS ZB-WZ homojunction was designed to improve charge separation efficiency•Bandgap engineering improved the hydrogen production from glucose photoreforming•Optimized Zn0.6Cd0.4S ZB-WZ exhibited high lactic acid yield and selectivity•Rational photocatalyst design realizes biomass valorization and H2coproductionChemistry; Catalysis; Engineering; Materials Science
