期刊
JOURNAL OF WATER PROCESS ENGINEERING
卷 52, 期 -, 页码 -出版社
ELSEVIER
DOI: 10.1016/j.jwpe.2023.103519
关键词
Multiple-hole DBD; Advanced oxidation process (AOP); Plasma-based AOP; Plasma Fenton
The combination of a dielectric barrier discharge (DBD) plasma system and Fe3O4 Fenton catalyst improved the decomposition efficiency and oxidation rate of organic pollutants. Compared to other AOP systems, the combined plasma Fenton system achieved >99% degradation of 200 mg L-1 dyes within 35 min, while the Fe3O4 Fenton system and Ozone (O3) system achieved less degradation. Additionally, the plasma Fenton system effectively degraded >92% of tetracycline and ciprofloxacin (TC, CIP: 10 mg L-1) within 5 min, in contrast to the Fe3O4 Fenton system.
In this study, the decomposition efficiency and oxidation rate of organic pollutants were improved using a combination of a dielectric barrier discharge (DBD) plasma system and Fe3O4 Fenton catalyst, a representative advanced oxidation process (AOP). The combined plasma Fenton system showed >99 % degradation of 200 mg L-1 dyes within 35 min, while other AOP systems achieved lesser degradation of the same concentration of dyes in 40 min: no degradation in the Fe3O4 Fenton system and <25 % in the Ozone(O3) system. Additionally, >92 % of tetracycline and ciprofloxacin (TC, CIP: 10 mg L-1) was effectively degraded in the plasma Fenton system within 5 min, in contrast to the Fe3O4 Fenton system. The rapid degradation of organic compounds was attributed to various oxidant species, including O3, H2O2, and center dot OH, from the reaction between the plasma electrode and Fenton catalyst. By analyzing chemically active species and interfacial reactions of the multiplehole DBD underwater plasma Fenton system, we improved the accessibility of AOP element technology and proposed a research foundation for the decomposition reaction, thereby providing a theoretical basis for developing this technology.
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