Revealing the crucial role of Carbon-Centered radicals in UV/PAA process for trace amounts of organic contaminants removal

Abstract

Peracetic acid (PAA) is a promising peroxyacid to combine with ultraviolet (UV) to eliminate trace amounts of organic contaminants (TrOCs), with growing importance in water treatment. In spite of a large number of research on UV/PAA process, the underlying mechanism still require further investigation, due to the difficulties in analyzing the carbon-centered radicals. Here we demonstrated the crucial roles of the carbon-centered radicals (namely CH3C(O)OO), via electron paramagnetic resonance (EPR) and kinetic models, with concentration of 4 orders magnitude higher than that of OH. Then, the theoretical calculation using density functional theory (DFT) showed that CH3C(O)OO and OH tended to attack phenol mostly through the route of radical adduct formation. The generated CH3C(O)OO and OH adducts may undergo further reactions to produce catechol and hydroquinone. Further, the environmental applicability of UV/PAA process for TrOC abatement was evaluated, including the effects of pH, PAA dosage, water constituents, as well as the variation of acute toxicity. Different from the OH-dominated process, kinetic analysis revealed that CH3C(O)OO was almost immune to the presence of water constituents, leading to the outperformance of UV/PAA process in actual water samples. Our present study could inform the application of UV/PAA process in water and wastewater treatment.