Preparation of Co3O4@carbon nanotubes modified ceramic membrane for simultaneous catalytic oxidation and filtration of secondary effluent

To improve the efficiency of wastewater reclamation, a novel Co3O4@carbon nanotubes modified ceramic membrane (Co3O4@CNT-CM) was prepared in this work for simultaneous catalytic peroxymonosulfate (PMS) oxidation and filtration of secondary effluent. The synthesized Co3O4@CNT catalyst showed better dispersibility with more active sites exposed, and Co3O4@CNT-CM exhibited relatively smooth surface, higher permeate flux and excellent catalytic PMS ability. The antifouling and water purification performance of Co3O4@CNT-CM were systematically investigated in secondary effluent purification. With the dual effect of catalytic oxidation and filtration, the organic pollutants were observably reduced. Fluorescent components were also significantly removed, and more macromolecular substances were degraded into small molecular substances. The flux of Co3O4@CNT-CM was significantly improved, with the reversible and irreversible resistances decreased by 82.5% and 78.6%, individually. With respect to the fouling mechanism, the volume entering the stage of cake filtration dramatically increased. The prepared Co3O4@CNT-CM accelerated the generation of various active species for oxidative degradation of pollutants, thus improving the antifouling performance of membrane. These results demonstrated the application potential of Co3O4@CNT-CM for wastewater treatment and reclamation.

Automated summary

In this study, a novel Co3O4@carbon nanotubes modified ceramic membrane (Co3O4@CNT-CM) was prepared for simultaneous catalytic peroxymonosulfate (PMS) oxidation and filtration of secondary effluent. The Co3O4@CNT catalyst showed good dispersibility and a large number of active sites, and the Co3O4@CNT-CM had a smooth surface, high permeate flux, and excellent catalytic PMS ability. The Co3O4@CNT-CM demonstrated enhanced antifouling and water purification performance in the treatment of secondary effluent.