个人信息Personal Information
教授
硕士生导师
性别:女
毕业院校:九州工业大学
学位:博士
所在单位:生物工程学院
学科:生物工程与技术. 生物化学与分子生物学. 药剂学
办公地点:生物工程学院(西部校区)
CFC/PVDF/GO-Fe3+ membrane electrode and flow-through system improved E-Fenton performance with a low dosage of aqueous iron
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论文类型:期刊论文
发表时间:2018-03-20
发表刊物:SEPARATION AND PURIFICATION TECHNOLOGY
收录刊物:SCIE、EI
卷号:193
页面范围:220-231
ISSN号:1383-5866
关键字:Membrane cathode; Flow-through catalytic membrane; E-Fenton
摘要:In this research, we designed a sandwiched electrode membrane filtration system and examined the flow through E-Fenton performance. The electrochemically active cathodic membrane (CFC/PVDF/GO-Fe3+) was prepared by modifying a PVDF micro-filtration membrane with carbon fiber cloth, graphene oxide and ferric ion, to support the flow-through E-Fenton process. The Fe content of the prepared CFC/PVDF/GO-Fe3(+) membrane was 6.458 mu g Fe/cm(2) with a membrane thickness of 200 mu m and 5% GO doping. An insulating spacer made of polyester filter cloth was placed between CFC/PVDF/GO-Fe3+ membrane cathode and carbon fiber cloth anode to form the sandwiched electrode stack. Flow-through H2O2 electrochemical generation experiment indicated 2-electron ORR was the dominant reaction on CFC cathode at optimum applied voltage of 1.6-1.8 V, H2O2 production increased with the increment of flux in flow-through process, and 0.04 M Na2SO4 was adequate to support to the flow-through electrochemical reaction. E-Fenton reaction happened mainly in the membrane matrix and boundary layer, therefore Fe2+ dosage (0.01 mM and 0.025 mM with different sandwiched electrode stack configuration) was necessary to achieve maximum production of HO center dot which was found to be the dominant ROS. Oxalate oxidation experiments suggested that the CFC/PVDF/GO-Fe3+ membrane had excellent stability in proper pH electrolyte solution and selected configuration of sandwiched electrode stack. Rhodamine B degradation in CMB (completely mixed batch reactor) mode followed pseudo-first-order kinetics, and a regenerative E-Fenton performance was confirmed due to the in-situ regeneration of Fe2+ on membrane cathode. The decolorization rate of 10 mg/L Rhodamine B was similar to 75% in CSTR (continue stirred tank reactor) mode. This study highlights the potential of modified the polymeric membranes with GO and carbon fiber cloth as the cathodic electrochemical membrane for effective water treatment.