A novel combination of bioelectrochemical system with peroxymonosulfate oxidation for enhanced azo dye degradation and MnFe2O4 catalyst regeneration
Xu, Hengduo; Quan, Xiangchun; Chen, Liang
发表期刊CHEMOSPHERE
ISSN0045-6535
2019-02
卷号217页码:800-807
关键词MnFe2O4 Regeneration Peroxymonosulfate Azo dye Microbial fuel cell
研究领域Environmental Sciences & Ecology
DOI10.1016/j.chemosphere.2018.11.077
产权排序[Xu, Hengduo; Quan, Xiangchun; Chen, Liang] Beijing Normal Univ, Sch Environm, State Key Lab Water Environm Simulat, Key Lab Water & Sediment Sci,Minist Educ, Beijing 100875, Peoples R China; [Xu, Hengduo] Chinese Acad Sci, Yantai Inst Coastal Zone Res, Key Lab Coastal Biol & Utilizat, Yantai 264003, Shandong, Peoples R China
作者部门海岸带信息集成与综合管理实验室
英文摘要Advanced oxidation process (AOP) based on peroxymonosulfate (PMS) activation was established in microbial fuel cell (MFC) system with MnFe2O4 cathode (MFC-MnFe2O4/PMS) aimed to enhance azo dye degradation and catalyst regeneration. The effects of loading amount of MnFe2O4 catalyst, applied voltage, catholyte pH and PMS dosage on the degradation of Orange II were investigated. The stability of the MnFe2O4 cathode for successive PMS activation was also evaluated. The degradation of Orange was accelerated in the MFC-MMnFe2O4/PMS with apparent degradation rate constant increased to 1.8 times of that in the MnFe2O4/PMS control. A nearly complete removal of Orange II (100 mg L-1) was attained in the MFC-MnFe2O4/PMS under the optimum conditions of 2 mM PMS, 10 mg cm(-2) MnFe2O4 loading, pH 7 -8 and 480 min reaction time. MFC driven also extended the longevity of the MnFe2O4 catalyst for PMS activation due to the in-situ regeneration of congruent to Mn2+ and congruent to Fe2+ through accepting electrons from the cathode, and over 80% of Orange II was still removed in the 7th run. Additionally, the MFC-MnFe2O4/PMS system could recover electricity during Orange II degradation with a maximum power density of 206.2 +/- 3.1 mW m(-2). PMS activation by MnFe2O4 was the primary pathway for SO4 generation, and SO4 based oxidation was the primary mechanism for Orange II degradation. MFCs driven coupled with PMS activated AOP systems provides a novel strategy for efficient and persistent azo dye degradation. (C) 2018 Elsevier Ltd. All rights reserved.
文章类型Article
资助机构Natural Science Foundation of China [51678055]
收录类别SCI
语种英语
关键词[WOS]MICROBIAL FUEL-CELL ; EFFICIENT DEGRADATION ; HETEROGENEOUS ACTIVATION ; ORANGE II ; CARBON ; DECOLORIZATION ; GENERATION ; REDUCTION ; REMOVAL ; ACID
研究领域[WOS]Environmental Sciences
WOS记录号WOS:000456223500087
引用统计
被引频次:43[WOS]   [WOS记录]     [WOS相关记录]
文献类型期刊论文
条目标识符http://ir.yic.ac.cn/handle/133337/24630
专题中国科学院海岸带环境过程与生态修复重点实验室_海岸带信息集成与战略规划研究中心
作者单位1.Beijing Normal Univ, Sch Environm, State Key Lab Water Environm Simulat, Key Lab Water & Sediment Sci,Minist Educ, Beijing 100875, Peoples R China;
2.Chinese Acad Sci, Yantai Inst Coastal Zone Res, Key Lab Coastal Biol & Utilizat, Yantai 264003, Shandong, Peoples R China
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Xu, Hengduo,Quan, Xiangchun,Chen, Liang. A novel combination of bioelectrochemical system with peroxymonosulfate oxidation for enhanced azo dye degradation and MnFe2O4 catalyst regeneration[J]. CHEMOSPHERE,2019,217:800-807.
APA Xu, Hengduo,Quan, Xiangchun,&Chen, Liang.(2019).A novel combination of bioelectrochemical system with peroxymonosulfate oxidation for enhanced azo dye degradation and MnFe2O4 catalyst regeneration.CHEMOSPHERE,217,800-807.
MLA Xu, Hengduo,et al."A novel combination of bioelectrochemical system with peroxymonosulfate oxidation for enhanced azo dye degradation and MnFe2O4 catalyst regeneration".CHEMOSPHERE 217(2019):800-807.
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