Transition Metal Sulfide Cocatalysts: Applications and Challenges in Photocatalytic Hydrogen Production

doi:10.1007/s40242-025-5103-z

Abstract

Abstract: Hydrogen (H₂), as a pivotal zero-carbon energy carrier, plays a critical role in the global energy transition, with its efficient production being paramount. Photocatalytic water splitting, driven by solar energy to produce H₂, is regarded as an ideal pathway for green hydrogen generation. However, its efficiency is still restricted by factors including narrow light-absorption spectra, elevated carrier recombination rates, and slow surface reaction kinetics. Among various strategies for enhancing photocatalytic activity, the development of cocatalyst loading has garnered significant attention due to its remarkable efficiency, stability, cost-effectiveness, and the ability to finely tune its performance. In the pursuit of optimizing catalysts for the green H₂ production, researchers have delved into the design of cocatalysts by focusing on four pivotal aspects:band alignment and interfacial engineering, crystal phase modulation, precise regulation of active sites, and photothermal synergy effects. Transition metal sulfides (TMSs) have emerged as promising alternatives to noble metal cocatalysts, possessing unique electronic structures, tunable active sites, and interfacial synergistic effects. This review systematically summarizes recent advancements in TMS-based cocatalysts, including MoS₂, NiS, WS₂, and CuS, for photocatalytic H₂ evolution. Furthermore, addressing practical challenges in TMS applications, we propose future research directions focusing on improving long-term material stability, developing environmentally friendly material designs, enabling low-cost, scalable synthesis, promoting interfacial charge transfer and advancing integrated device engineering. These efforts aim to provide theoretical foundations and technological breakthroughs for constructing efficient, economical, and sustainable solar-tohydrogen conversion systems.

Key words: Cocatalyst, Photocatalysis, Hydrogen evolution reaction (HER), Metal sulfide, Water-splitting

ZHOU Yu, WANG Weikang, LI Jinhe, REN Wei, WANG Lele, LIU Qinqin. Transition Metal Sulfide Cocatalysts: Applications and Challenges in Photocatalytic Hydrogen Production[J]. Chemical Research in Chinese Universities, 2025, 41(4): 687-703.

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