NIR light responsive MoS2 nanomaterials for rapid sterilization: Optimum photothermal effect via sulfur vacancy modulation

As the increasing problem of bacterial resistance has become the threaten to human health and environmental protection, the explorations of efficient and environmental-friendly antimicrobial agents are highly desired. Recently, vacancy engineering is regarded as the quite novel strategy to regulate the electronic structure of semiconductor Nanomaterials (NMs), largely improving their photocatalytic performance in rapid and safe sterilization. In this study, molybdenum sulfide (MoS2) NMs with different concentrations of sulfur vacancies (Vs) were synthesized through annealed at different temperature (i.e., 150 degrees C, 250 degrees C and 350 degrees C), providing the platform for studying the efficient bacterial inactivation of defective MoS2 NMs under the near-infrared light irradiation. The optimum photothermal conversion efficiency could be achieved with the appropriate concentration of Vs, through improving the light adsorption and preventing the recombination of photogenerated e- /h+ pairs. In addition, MoS2 NMs with the abundant Vs exhibited hyperthermia and strong binding ability to bacteria, leading to the severe damage to cell wall integrity, energy supply and antioxidant system. Collectively, these results focused on the relationship between optimum antibacterial efficiency and appropriate concentrations of Vs, providing new insights into the designation of photocatalysts with highly efficient sterilization.

Automated summary

In this study, MoS2 NMs with varying concentrations of sulfur vacancies (Vs) were synthesized and showed improved photothermal conversion efficiency for efficient antibacterial activity under near-infrared light irradiation.