Abstract
ZnO/Au is expected to exhibit catalytic properties by absorbing ultraviolet and visible light because ZnO and Au nanoparticles can absorb ultraviolet and visible light, respectively. Doping studies on Au nanoparticles on ZnO (ZnO/Au) have been conducted to expand the absorption wavelength range. This study generates ZnO/Au particles by an ultrasonic spray pyrolysis method (USP). To prevent particle aggregation, Triton X-100, a non-ionic surfactant, is added, and its effects are examined. The generated ZnO/Au particles are characterized using different methods. SEM reveals the particle size is several micrometers, while XRD analysis indicates that ZnO and a metallic Au crystalline are present. The TEM images of the particles show that the Au crystals are well dispersed in the inner and outer portions of ZnO. UV-Vis spectroscopy confirms that the smaller the Au particle size, the higher the visible absorption peak near 400 nm. Adding Triton X-100 shifts the absorption peak toward the longer wavelength side but improves the aggregation of Au particles.
Highlights
In developing countries, environmental pollution of organic cloth dyes and industrial wastewater is a very serious issue
ZnO/Au particles with Au doped on ZnO are successfully generated by the ultrasonic spray pyrolysis method
Triton X-100 is added to inhibit the agglomeration of Au particles, it promotes Au particle growth
Summary
Environmental pollution of organic cloth dyes and industrial wastewater is a very serious issue. It is generally treated using adsorption and chemical coagulation methods (Sauer et al, 2002; Wang et al, 1998; Matthews, 1991; Galindo et al, 2001). Because photocatalysts are especially promising, various photocatalysts are being studied and produced Oxide photocatalysts such as SnO2, TiO2, WO2, and Fe2O3 can effectively decompose organic pollutants under ultraviolet light irradiation. ZnO has attracted much attention due to its physical and chemical stability Since it has a high oxidation property, it should realize practical applications as a photodecomposition catalyst of organic pollutants. It can be used to remove volatile organic compounds (VOCs) coated on building materials
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