Removal of methylisothiazolinone biocide from wastewater by VUV/UV advanced oxidation process: Kinetics, mechanisms and toxicity

Methylisothiazolinone (MIT) is frequently used as antimicrobial in household and industrial products, and poses ecological and health risks to aquatic organisms and humans. In this study, vacuum ultraviolet (VUV)/ultraviolet (UV) irradiation was found highly efficient for removal of MIT. The rate constant of MIT degradation (kobs) under VUV/UV irradiation was 3.75 mu Einstein(-1) cm(2), which was around 12.5 times higher than that under UV irradiation. The center dot & nbsp;OH concentration during the VUV/UV process was 1.0 x 10(-12) M. The contributions of UV photolysis and .center dot & nbsp;OH oxidation to MIT degradation under VUV/UV irradiation were 7.3% and 92.7%, respectively. The optimum solution pH (6.0-7.1) gave kobs 33%-39% higher than those at pH 3.9 and 9.3. CO32- /HCO(3)(- )inhibitedMIT degradation and the kobs decreased by 74% when the concentration of CO32- /HCO3- was increased to 1 mM. The order of MIT removal efficiency under VUV/UV irradiation was ultrapure water > secondary effluent > reverse osmosis (RO) concentrate, because of the light screening and .& nbsp;OH quenching effect of actual wastewater. In RO concentrate, the rate constant of MIT degradation under VUV/UV irradiation was 22% higher than that obtained under UV irradiation. The reduction of TOC, UV254, and total fluorescence regional integration of the RO concentrate during VUV/UV process were 7.2%, 34.9%, and 52.3%, respectively. Twelve main transformation products of MIT were identified after VUV/UV degradation. The main degradation mechanisms of MIT were sulfur atom oxidation and hydroxyl addition. Quantitative structure-activity relationship analysis showed that VUV/UV degradation was an efficient method to remove the toxicity of MIT.

Automated summary

Methylisothiazolinone (MIT) is efficiently degraded by vacuum ultraviolet (VUV)/ultraviolet (UV) irradiation, with the presence of .center dot & nbsp;OH as the main oxidant. The degradation efficiency of MIT under VUV/UV irradiation is higher than under UV irradiation, and is influenced by solution pH and the concentration of CO32- /HCO3-. The study also identified the main degradation mechanisms of MIT as sulfur atom oxidation and hydroxyl addition, with VUV/UV degradation being an effective method to remove MIT toxicity.