Organic polymer membranes have been widely used for wastewater treatment.Due to occurrence of irreversible membrane contamination,the replacement of the membrane after the performance decay leads to the generation of a large number of discarded membranes.How to realize the reuse of these waste polymer films has important economic and environmental value.In this study,a carbonaceous material with both ultramicroporous,mesoporous,and macroporous structures was prepared by a simple pyrolysis remodeling reaction using waste hollow fiber membranes as a template.The differences in the adsorption performance of the waste membrane?derived activated carbon and commercial activated carbon were investigated based on the structural characterizations of the carbonaceous materials.The kinetic and thermodynamic processes for the adsorption removal of typical aromatic hydrocarbon organic contaminants and antibiotics from water were investigated.It was found that the the waste membrane carbon with hierarchical pore structure had a higher removal capacity for aromatic hydrocarbon organic pollutants than commercial carbon,while the adsorption performance for antibiotics such as ciprofloxacin,carbamazepine and sulfadiazine was lower than that of commercial carbon.

The efficient removal of perfluorooctanoic acid (PFOA) from contaminated water remains a challenge due to the very stable carbon?fluorine bonds in perfluorinated compounds.In this experiment,nanosecond pulsed dielectric barrier discharge (DBD) plasma was used to degrade PFOA,a difficult?to?degrade organic pollutant in water,and the effects of discharge parameters such as discharge atmosphere,discharge power,gas flow rate,and liquid flow rate,as well as the reaction conditions,on the removal rate of PFOA were investigated in the reaction.The experimental results showed that under the conditions of the discharge atmosphere of argon,discharge power of 11.84 W,gas flow rate of 3.33 L/min,and liquid flow rate of 0.28 L/min,DBD had a better degradation effect on PFOA,and the removal rate could reach more than 94.0% after 60 min of reaction.Combined with emission spectroscopy and free radical burst analysis,it was determined that e^-,?OH,H₂O₂, and O₃ were the main active species to break the molecular structure of PFOA and realize the efficient degradation of the reactants,and thus could provide an effective solution for the removal of PFOA in water.