Crystal violet (CV), a cationic dye, has been established to be an extremely potent carcinogen, a mitotic toxin, and poisonous to mammalian cells. As a consequence, it is imperative to remove this specific dye before it is released into the environment because its presence inevitably has a devastating effect on humankind. The photocatalyst-mediated degradation of CV is a rapidly developing method of eliminating this hazardous dye from aqueous solutions, as demonstrated by the extensive reporting of its efficacy in recent times. In this study, we explore the photocatalytic activity of pure SnO2, CdS and SnO2/CdS nanocomposites which were fabricated by a facile sol-gel technique. Field emission scanning electron microscopic (FESEM) analysis revealed a cauliflower-like morphology for the SnO2/CdS nanocomposite. The optical band gaps of the nanoparticles were found to be 2.41, 2.04 and 2.28 eV for the SnO2, CdS, and SnO2/CdS, respectively. Moreover, the SnO2/CdS photocatalyst exhibits greater photocatalytic activity (73% degradation efficiency after 75 min) for the degradation of CV than that of the pure SnO2 and CdS nanomaterials. This enhanced performance is attributed to enhanced charge separation and reduced charge recombination rates in the SnO2/CdS photocatalyst activity, such that it could be used as a potential material to reduce water pollution in an economically viable way.Graphical Abstract:
Highlights: SnO2/CdS heterostructure catalyst was prepared using a sol-gel method.The heterostructure exhibit higher photocatalytic degradation efficiency of 73% towards crystal violet dye within 75 min under UV light irradiation.This could be due to better charge separation and rapid suppression of charge recombination in the SnO2/CdS heterostructure.The heterostructure exhibit good reusability and cyclic stability.Prepared heterostructure is a potential catalyst to minimize water pollution in a cost–economical way.