Effect of surface iodine atom on dissolved oxygen activation for enhanced photocatalytic advanced oxidation processes over Bi2WO6 nanosheet

Facing with the growing demand of wastewater purification in industry and human being, the effect of catalyst on the activation of dissolved oxygen molecule plays a critical role for advanced oxidation processes (AOPs). Surface I atom-doped Bi₂WO₆ (I-BWO) sheet was successfully synthesized through a two-step hydrothermal method. The decomposition degradation efficiencies of p-chlorophenol and rhodamine B pollutants for the optimized 2I-BWO sample were 14.5 times and 11.0 times than those of the pristine Bi₂WO₆. The MS results about intermediates explained the mechanism of 4-CP and RhB degradation. Facing with other four organic pollutants such as methylene blue, methyl orange, 4-nitrophenol and tetracycline, the COD removal efficiencies were also observably declined through the photocatalysis. Based on experimental and computational results, the surface I atom caused the disorder of surface structure, forming superior adsorption and activation site of dissolved oxygen molecule. Multiple oxidizing species including superoxide radical, hydroxide radical, singlet oxygen and hydrogen peroxide, were proven to be generated on the modified surface of Bi₂WO₆ sheet. This study contributes to understanding the impact of in iodine doping on surface structural regulation, thereby facilitating rational design of efficient photocatalysts for AOPs.