Cobalt-based materials are promising catalysts for activating peroxymonosulfate (PMS) to degrade organic pollutants. Among various cobalt-based catalysts, the alteration in cobalt species and the reactive species produced are not fully understood. Herein, four materials were synthesized by controlling synthesis methods and doping of g-C3N4 to regulate cobalt species. Through two methods, ZIF/Co and Co3O4, whose main cobalt species are Co-O/Co-N and Co=O/O-Co=O, were synthesized. On this basis, ZIF/Co-CN and Co3O4-CN were synthesized by adding g-C3N4. Then, the four materials were used to activate PMS for carbamazepine (CBZ) degradation, focusing on the correlation between active sites and reactive species. Co=O/O-Co=O mainly led to the formation of free radicals, while Co-N tended to produce non-free radicals. The addition of g-C3N4 would facilitate non-free radical catalysis by promoting the conversion of Co-O to Co-N and enhancing the catalytic role of C and N. Finally, the systems with a high proportion of non-free radicals showed better degradation performance when multiple pollutants co-existed, and reactive species may be selective to different pollutants. The findings have significance for the synthesis design of cobalt-based catalysts and the regulation of reactive species to degrade different pollutants practically.
Keywords: cobalt species; cobalt-based catalyst; pollutant degradation; reactive species.
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