The mechanism of water pollutant photodegradation by mixed and core-shell WO3/TiO2 nanocomposites

Environmental pollution is one of the biggest concerns in the world today, and solar energy-driven photocatalysis is a promising method for decomposing pollutants in aqueous systems. In this study, the photocatalytic efficiency and catalytic mechanism of WO3-loaded TiO2 nanocomposites of various structures were analyzed. The nanocomposites were synthesized via sol-gel reactions using mixtures of precursors at various ratios (5%, 8%, and 10 wt% WO3 in the nanocomposites) and via core-shell approaches (TiO2@WO3 and WO3@TiO2 in a 9 : 1 ratio of TiO2 : WO3). After calcination at 450 degrees C, the nanocomposites were characterized and used as photocatalysts. The kinetics of photocatalysis with these nanocomposites for the degradation of methylene blue (MB+) and methyl orange (MO-) under UV light (365 nm) were analyzed as pseudo-first-order reactions. The decomposition rate of MB+ was much higher than that of MO-, and the adsorption behavior of the dyes in the dark suggested that the negatively charged surface of WO3 played an important role in adsorbing the cationic dye. Scavengers were used to quench the active species (superoxide, hole, and hydroxyl radicals), and the results indicated that hydroxyl radicals were the most active species; however, the active species were generated more evenly on the mixed surfaces of WO3 and TiO2 than on the core-shell structures. This finding shows that the photoreaction mechanisms could be controlled through adjustments to the nanocomposite structure. These results can guide the design and preparation of photocatalysts with improved and controlled activities for environmental remediation.

Automated summary

Environmental pollution is a global concern, and solar energy-driven photocatalysis shows promise for pollutant decomposition in water systems. This study analyzed the efficiency and mechanism of WO3-loaded TiO2 nanocomposites with different structures. The nanocomposites were synthesized using sol-gel reactions and core-shell approaches, and their photocatalytic activity was analyzed for the degradation of methylene blue and methyl orange. The results showed that adjusting the nanocomposite structure could control the photoreaction mechanisms. These findings have implications for the design of photocatalysts for environmental remediation.