A Z-Scheme Strategy that Utilizes ZnIn2 S4 and Hierarchical VS2 Microflowers with Improved Charge-Carrier Dynamics for Superior Photoelectrochemical Water Oxidation.

One of the major limiting factors for efficient photoelectrochemical water oxidation is the fast recombination kinetics of photogenerated charge carriers. Herein, we propose a model system that utilizes ZnIn2 S4 and hierarchical VS2 microflowers for efficient charge separation through a Z-scheme pathway, without the need for an electron mediator. An impressive 18-fold increase in photocurrent was observed for ZnIn2 S4 -VS2 compared to ZnIn2 S4 alone. The charge-transfer dynamics in the composite were found to follow a Z-scheme pathway, which resulted in decreased charge recombination and greater accumulation of the surface charge. Furthermore, slow kinetics of the surface reaction in the ZnIn2 S4 -VS2 composite correlated to an increased surface-charge capacitance. This feature of the composite material facilitated partial storage of the photogenerated charge carriers (e- /h+ ) under illumination and dark-current conditions, thus storing and utilizing solar energy more efficiently.