Kinetics and pathways of the degradation of PPCPs by carbonate radicals in advanced oxidation processes.

The carbonate radical (CO) is a typical secondary radical observed in engineering and natural aquatic systems. This study investigated the degradation kinetics of 20 pharmaceuticals and personal care products (PPCPs) by CO and the transformation pathways of a typical PPCP (naproxen) that is susceptible to CO. CO is highly selective for compounds containing aniline and phenolic hydroxyl groups as well as naphthalene rings, such as sulfamethoxazole, sulfamethazine, salbutamol, propranolol, naproxen, and macrolide antibiotics such as azithromycin, for which the second-order rate constants range from 5.6 × 10 Ms to 2.96 × 10 Ms. A good linear relationship is observed between the natural logarithms of k and the negative values of the Hammett Σσ constant for aromatic PPCPs, indicating that electron-donating groups promote the attack of benzene derivatives by CO. The contribution of CO to naproxen degradation is significant in different processes such as UV/HO, UV/persulfate, UV/chlorine, and UV/monochloramine, in the presence of HCO, which compensates for the decreased contributions of primary radicals. In particular, the formation of CO increases the first-order rate constant of naproxen by 127% in UV/monochloramine in the presence of 50 mM HCO compared to that without HCO. Natural organic matter (NOM) exerts a slight scavenging effect on CO, decreasing the inhibition effect of NOM on the degradation of naproxen by UV/HO in the presence of HCO. The pathways involved in the transformation of naproxen by CO include decarboxylation, hydroxylation, ketonization, demethylation and aldolization. In addition, the alteration of the genotoxicity during naproxen degradation by CO was negligible.