Abstract
Novel ZnS–Cu7S4 nanohybrid supported on chitosan matrix, as an ideal photocatalyst, was fabricated by the sonochemical method wherein high-resolution transmission electron microscopy (HRTEM) and X-ray powder diffraction (XRD) analysis confirmed the co-existence of both ZnS and Cu7S4; presence of vacancy sites in ZnS was verified by electron paramagnetic resonance (EPR) analysis and their introduction could promote two-photon excitation facilitated visible light response and charge transport/separation. The type II interface is formed in the ZnS–Cu7S4/Chitosan heterojunction owing to interstitial states that promote charge separation. The ZnS–Cu7S4/Chitosan was used for the photodegradation of a pharmaceutical pollutant, p-chlorophenol (PCP); over 98.8% of PCP photodegradation was achieved under visible-light irradiation where the ensued ·O2− and ·OH serve a key role in the photodegradation of PCP. In vitro cytotoxicity studies substantiated that the ZnS–Cu7S4/Chitosan is nontoxic to the ecosystem and human beings and endowed with promising photodegradation properties and accessibility via an environmentally friendly design, bodes well for its potential remediation applications.
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•ZnS–Cu7S4/chitosan type II heterojunction showed 98.8% photodegradaion of p-chlorophenol.•Defect engineering to promote synergistic charge separation and visible-light absorption.•The Cu7S4 and ZnS NPs appears to be in spine and nanocube shaped.•Formation of both ·O2− and ·OH radicals to boost pollutants degradation.•The In vitro cytotoxicity assay suggests that ZnS–Cu7S4/chitosan is non-toxic.