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降解喹啉的微生物燃料电池的产电特性研究
引用本文:张翠萍,王志强,刘广立,骆海萍,张仁铎. 降解喹啉的微生物燃料电池的产电特性研究[J]. 环境科学学报, 2009, 29(4): 740-746
作者姓名:张翠萍  王志强  刘广立  骆海萍  张仁铎
作者单位:中山大学环境科学与工程学院,广州,510275;清华大学环境科学与工程系,环境模拟与污染控制国家重点联合实验室,北京,100084
基金项目:广东省环境污染控制与修改技术重点试验室开发基金,国家自然科学基金,环境模拟与污染控制国家重点联合实验室专项基金 
摘    要:通过构建双极室微生物燃料电池(Microbial fuel cell,MFC),对喹啉的降解及MFC的产电性能进行了研究.试验结果表明,当喹啉初始浓度为500 mg·L-1,葡萄糖与喹啉浓度之比为1:1,3:5,1:5时,MFC的最大输出电压分别为558 mV、469 mV、328 mV,运行周期分别为56.4 h、70h、82.5 h;最大功率密度分别为173 mW·m-2、122 mW·m-2、60 mW·m-2(按阳极截面积计算)或者35 W·m-3、24 W·m-3、12 W·m-3(按阳极室有效容积计算).MFC可实现对喹啉的高效降解,但葡萄糖的浓度对喹啉的降解速率有较大影响.当葡萄糖浓度分别为500 mg.L-1、300mg·L-1和100 mg·L-1时,使500 mg·L-1喹啉完全降解的时间分别为6 h、24 h和72 h.MFC闭路条件下对喹啉的降解速率高于开路厌氧条件下的喹啉降解速率约10%.MFC对喹啉的降解与产电速率之间存在差距,喹啉被快速降解至较低浓度(<5rag·L-1)后,MFC的产电性能才达到最优.MFC以用喹啉和葡萄糖作为混合燃料时,可以在实现高效降解喹啉的同时可稳定地向外输出电能,这为杂环芳烃类难降解有机物的高效低耗处理提供了新的途径.

关 键 词:微生物燃料电池  喹啉降解  共代谢  产电性能
收稿时间:2008-06-24
修稿时间:2008-10-11

Power generation from quinoline degradation using a microbial fuel cell
ZHANG Cuiping,WANG Zhiqiang,LIU Guangli,LUO Haiping and ZHANG Renduo. Power generation from quinoline degradation using a microbial fuel cell[J]. Acta Scientiae Circumstantiae, 2009, 29(4): 740-746
Authors:ZHANG Cuiping  WANG Zhiqiang  LIU Guangli  LUO Haiping  ZHANG Renduo
Affiliation:ZHANG Cuiping1,WANG Zhiqiang2,LIU Guangli1,LUO Haiping1,ZHANG Renduo1 1.School of Environmental Science , Engineering,Sun Yat-sen University,Guangzhou 510275 2.Environmental Simulation , Pollution Control State Key Joint Laboratory,Department of Environmental Science , Engineering,Tsinghua University,Beijing 100084
Abstract:Adouble-chamber Microbial Fuel Cell(MFC)was constructed to investigate quinoline degradation and power generation.Experiments were conducted using an initial quinoline concentration of 500 mg·L-1 with different glucose concentrations(500 mg·L-1,300 mg·L-1,and 100 mg·L-1)as the MFCfuel.Results showed that maximum voltages of 558 mV,469 mVand 328 mVcorresponding to cycle times of 56.4 h,70 h and 82.5 h were obtained for fuels with glucose to quinoline ratios of 1:1,3:5,and 1:5,respectively.Correspondingly,the maximal area power densities were 173 mW·m-2,122 mW·m-2,60 mW·m-2,and the maximal volumetric power densities were 35 W·m-3,24 W·m-3,12 W·m-3,and the times required to degrade quinoline completely were 6 h,24 h,and 72 h.Compared to open circuit control,the MFCwith closed circuit control enhanced quinoline biodegradation by 10%.Optimum power generation was obtained when quinoline was degraded to a low concentration(<5 mg·L-1).The results clearly demonstrated the feasibility of using the MFCto generate electricity using a quinoline and glucose mixture as fuel and simultaneously degrading the quinoline.The results offer a new method of enhancing biodegradation of recalcitrant contaminants,such as heterocyclic compounds,in practical applications.
Keywords:MFC  quinoline biodegradation  co-metabolism  power generation  
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