Abstract

Production of H2 from water splitting is challenging. Herein, we report an increased production of H2 on Zn0.5Cd0.5S (ZnCdS) in aqueous solution under a 420 nm LED lamp, via 4 wt % MCo2O4 (M = Mg, Cr, Mn, Fe, Co, Ni, Cu, and Zn). Without addition of sacrifices, the rate of H2 evolution (RH, in a unit of mmol g―1 h―1) was 0.0154 for ZnCdS, and 0.057―0.551 for MCo2O4/ZnCdS. On addition of Na2S/Na2SO3, the corresponding RH increased to 18.5 and 31.5―78.2, respectively. In both cases, no H2 was observed for MCo2O4. However, the RH obtained in presence of Na2S/Na2SO3 had a negative correlation with Ms and R2, respectively, where Ms was the magnetization degree of MCo2O4, and R2 was the charge transfer resistance for MCo2O4/ZnCdS at solid-liquid interface. Electrochemical measurement showed that MCo2O4/ZnCdS was more active than ZnCdS for proton reduction, water oxidation, and water(sulfide/sulfite) photo-oxidation, respectively. According to the solid photoluminescence, band parameters, and open circuit potentials, formation of a p-n junction is proposed, which facilitates the photoelectron transfer to ZnCdS for proton reduction, and the photohole transfer to MCo2O4 for water (sulfide/sulfite) oxidation. It is also proposed that the magnetic field of MCo2O4 inhibits the charge transfer between MCo2O4 and ZnCdS. This work suggests that MCo2O4 spinels are good co-catalysts, but their magnetization need to be minimized.

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