Abstract

Carbonate radical (CO3•−) has been proved to be an important secondary radical in advanced oxidation processes due to various radical reactions involved HCO3−/CO32−. However, the roles and contributions of CO3•− in organic micropollutant degradation have not been explored systematically. Here, we quantified the impact of CO3•− on the degradation kinetics of propranolol, a representative pollutant in the UV/peroxymonosulfate (PMS) system, by constructing a steady-state radical model. Substantially, the measured values were coincident with the predictive values, and the contributions of CO3•− on propranolol degradation were the water matrix-dependent. Propranolol degradation increased by 130% in UV/PMS system containing 10 mM HCO3−, and the contribution of CO3•− was as high as 58%. Relatively high pH values are beneficial for propranolol degradation in pure water containing HCO3−, and the contributions of CO3•− also enhanced, while an inverse phenomenon was shown for the effects of propranolol concentrations. Dissolved organic matter exhibited significant scavenging effects on HO•, SO4•−, and CO3•−, substantially retarding the elimination process. The developed model successfully predicted oxidation degradation kinetics of propranolol in actual sewage, and CO3•− contribution was up to 93%, which in indicative of the important role of CO3•− in organic micropollutant removal via AOPs treatment.

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