MoS2 and CdS photocatalysts for water decontamination: A review

Semiconductor photocatalytic technology, driven by solar energy, represents an attractive strategy to relieve or perhaps even resolve many environmental pollution issues. The semiconductor-based photocatalysts, MoS2 and CdS, have attracted considerable attention for water decontamination owing to their unique properties of tuneable bandgap, high absorption of visible light, and excellent electronic-charge transfer capability. In this review, the following topics are presented: the mechanism of semiconductor photocatalysis, the synthetic stra-tegies employed in preparing MoS2 and CdS nanostructured photocatalysts, and their applications in wastewater treatment. In addition, possible approaches to improve their photocatalytic performance, such as modification of morphology, shape, and crystallinity are discussed together with heteroatom doping, and metal sulfide, metal oxide, and carbon compound nanocomposite formation.

Automated summary

Semiconductor photocatalytic technology driven by solar energy is an attractive strategy to address environmental pollution issues. MoS2 and CdS, as semiconductor-based photocatalysts, have unique properties such as tunable bandgap, high absorption of visible light, and efficient charge transfer, making them ideal for water decontamination. This review covers the mechanism of semiconductor photocatalysis, synthesis strategies for MoS2 and CdS nanostructured photocatalysts, and their applications in wastewater treatment. It also discusses potential approaches to enhance their photocatalytic performance, including morphology modification, heteroatom doping, and nanocomposite formation with metal sulfides, metal oxides, or carbon compounds.