Abstract:
The use of solar energy for hydrogen (H2) production via water splitting is rapidly emerging as a promising clean energy source. Progress in this field depends on developing high-performance, stable catalysts that efficiently drive the hydrogen evolution reaction (HER). In this study, a simple hydrothermal method is employed to synthesize a medium-entropy quinary sulfide photocatalyst (Cd1-x-yNixMoyZn0.45S) capable of generating H2 directly from water without the use of additional cocatalysts. The quinary photocatalyst retains a distinct hexagonal lattice despite the partial substitution of Cd with earth-abundant elements Ni, Mo, and Zn, significantly reducing the Cd content without disrupting the crystalline phase. The optimal composition, Cd0.39Ni0.09Mo0.07Zn0.45S (CNMZS-3), exhibits a 6-fold enhancement in the H2 evolution rate of 2437.87 μmol g–1 h–1 compared to pristine CdS (419.75 μmol g–1 h–1), aided by engineered sulfur vacancies. CNMZS-3 also demonstrates excellent stability, maintaining its structural integrity and catalytic performance for 72 h with minimal degradation. Density functional theory (DFT) analyses reveal that the Mo sites serve as the most active centers for H adsorption, while Ni improves photoabsorption, creating a synergistic effect that boosts HER activity. Replacing the conventional oxygen evolution reaction (OER) with ethylene glycol (EG) oxidation further increases H2 production to 3746.74 μmol g–1 h–1 over 4 h, accompanied by the formate formation. Remarkably, CNMZS-3 also performs effectively in artificial seawater, achieving H2 evolution rate of 1786.79 μmol g–1 h–1. These findings highlight medium-entropy quinary sulfides as versatile bifunctional photocatalysts for H2 production from both freshwater and seawater, as well as for value-added chemical generation from EG.