Abstract
Cobalt-mediated activation of peroxymonosulfate (PMS) has been widely investigated for the oxidation of organic pollutants. Herein, we employ cobalt-doped Black TiO2 nanotubes (Co-Black TNT) for the efficient, stable, and reusable activator of PMS for the degradation of organic pollutants. Co-Black TNTs induce the activation of PMS by itself and stabilized oxygen vacancies that enhance the bonding with PMS and provide catalytic active sites for PMS activation. A relatively high electronic conductivity associated with the coexistence of Ti4+ and Ti3+ in Co-Black TNT enables an efficient electron transfer between PMS and the catalyst. As a result, Co-Black TNT is an effective catalyst for PMS activation, leading to the degradation of selected organic pollutants when compared to other TNTs (TNT, Co-TNT, and Black TNT) and other Co-based materials (Co3O4, Co-TiO2, CoFe2O4, and Co3O4/rGO). The observed organic compound degradation kinetics are retarded in the presence of methanol and natural organic matter as sulfate radical scavengers. These results demonstrate that sulfate radical is the primary oxidant generated via PMS activation on Co-Black TNT. The strong interaction between Co and TiO2 through Co–O–Ti bonds and rapid redox cycle of Co2+/Co3+ in Co-Black TNT prevents cobalt leaching and enhances catalyst stability over a wide pH range and repetitive uses of the catalyst. Electrode-supported Co-Black TNT facilitates the recovery of the catalyst from the treated water.
Highlights
Co-Black TNT is an effective catalyst for PMS activation, leading to the degradation of selected organic pollutants when compared to other TNTs
The observed organic compound degradation kinetics are retarded in the presence of methanol and natural organic matter as sulfate radical scavengers. These results demonstrate that sulfate radical is the primary oxidant generated via PMS activation on Co-Black TNT
Peroxymonosulfate (PMS)-activated oxidation has been investigated for water treatment and soil remediation through nonradical and radical pathways.[1−5] A nonradical mechanism involves the direct electron transfer from organic electron donor to PMS on catalyst surfaces (e.g., carbon nanotubes (CNT) and reduced graphene oxide, rGO) leading to the oxidation of organic compounds with the formation of sulfate (E0(HSO5−/SO42−) = 1.75 VNHE).[6−8] On the other hand, free radical pathways involve the formation of sulfate radical anions (E0(HSO5−/SO4 −) = 2.43 VNHE) generated from PMS by catalysts coupled with an external energy input to cleave the peroxide bond.[9]
Summary
Co-Black TNT is an effective catalyst for PMS activation, leading to the degradation of selected organic pollutants when compared to other TNTs The 4-CP removal activity was not changed in unbuffered solution, which demonstrates the marginal effect of phosphate buffer (Figure S1 in the Supporting Information) in the Co-Black TNT/PMS reaction system.
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