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pH值对"Fe0-厌氧微生物"体系去除2,4,6-三氯酚过程的影响

Keywords: 2,4,6-三氯酚,厌氧微生物,零价铁,降解

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Abstract:

考察了pH值对"Fe0-厌氧微生物"体系降解2,4,6,-三氯酚(2,4,6-TCP)效果的影响,结果表明:pH值是影响"Fe0-厌氧微生物"体系降解2,4,6-TCP效果的重要参数,初始pH值直接影响微生物活性和铁腐蚀,进而影响过程pH值变化,反过来又影响铁腐蚀和微生物活性,pH7.0~9.0的中性偏碱范围较适于厌氧微生物生长。Fe0与微生物对目标污染物的降解具有协同促进作用,其协同促进机制表现在3方面:Fe0与微生物对体系过程pH值具有互补调节作用,可将体系的pH值调节值适于微生物生长的中性范围;Fe0腐蚀产生的Fe2+和H2可为微生物代谢提供电子对和营养物质,从而促进生物还原脱氯的进行;Fe0的腐蚀过程直接对氯代有机物还原脱氯,而微生物又可促进Fe0腐蚀。

 References

[1]  谢治民,李建华,王海洋,等. Fe-厌氧微生物体系降解2,4,6-三氯酚. 化工环保,2009,29(2):105-108 Xie Z. M., Li J. H., Wang H. Y., et al. Degradation of 2,4,6-TCP by iron anaerobe system. Environmental Protection of Chemical Industry,2009,29(2):105-108(in Chinese)
[2]  胡俊,王建龙,程荣.γ 2辐照-O3 氧化联合作用下4-氯酚的降解研究.中国科学(B辑),2005,35(6):520-525
[3]  王建龙, Hegemann W. 微生物群落对多氯酚的脱氯特性及机理研究. 中国科学(B 辑), 2003,33(1):47-53
[4]  Wang J. L., Horan N., Stentiford E., et al. Bioadsorption of pentachlorophenol (PCP) from aqueous solution by activated sludge biomass. Bioresouce Technology, 2000,75(2):157-161
[5]  杜桂荣,孙占学,童少平,等. 催化臭氧氧化法分解2,4-二氯苯酚的研究. 化工环保, 2005,25(2):93-96 Du G. R., Sun Z. X., Tong S. P., The study on the ozonation of 2,4-DCP in aqueous solution. Environmental Protection of Chemical Industry, 2005,25(2):93-96(in Chinese)
[6]  孙振世,杨晔,陈英旭,等.纳米TiO2薄膜光催化降解2,4-二氯酚的动力学研究. 环境科学学报, 2003,23(6):716-720 Sun Z. S., Yang Y., Chen Y. X., et al.Photo catalytic degradation kinetics of 2,4-DCP on nanostructured TiO2 film. Acta Scientiae Circumstantiae, 2003,23(6):716-720(in Chinese)
[7]  皮运正, 王建龙. 臭氧氧化水中4-氯酚的机理和反应途径. 中国科学(B辑), 2006,36(1):87-92
[8]  Rosenthal H., Adrian L., Steiof M. Dechlorination of PCE in the presence of Fe0 enhanced by a mixed culture containing two Dehalococcoides strains. Chemosphere, 2004,55(5):661-669
[9]  Lampron K. J., Chiu P. C., Cha D. K. Reductive dehalogenation of chlorinated ethenes with elemental iron: The role of microorganisms. Water Research, 2001,35(13):3077-3084
[10]  Lee T., Tokunaga T., Suama A., et al. Efficient dechlorination of tetrachloroethylene in soil slurry by combined use of an anaerobic Desulfitobacterium sp. strain Y-51 and zero-valent iron. Biosci. Bioeng., 2001,92(5):453-458
[11]  Zhang W., Chen L., Chen H., et al. The effect of Fe0/Fe2+/Fe3+ on nitrobenzene degradation in the anaerobic sludge. Journal of Hazardous Materials, 2007,143(1-2):57-64
[12]  唐受印,戴友芝,汪大翚,等. 废水处理工程(第2版).北京:化学工业出社,2004
[13]  程婷,戴友芝,史雷,等. pH值对"Fe0-厌氧微生物"降解2,4-二氯酚的影响.环境化学, 2008,27(6):716-720 Cheng T., Dai Y. Z., Shi L., et al. Effect of pH on the process of Fe0 anearobic microorganism degradation 2,4-DCP. Environmental Chemistry, 2008,27(6):716-720(in Chinese)
[14]  李云巧. 实验室溶液制备手册.北京:化学工业出版社,2006
[15]  Kassenga G., Pardue J. H., Moe W. M., et al. Hydrogen thresholds as indicators of dehalorespiration in constructed treatment wet lands. Environmental Science & Technology, 2004,38(4):1024-1030
[16]  Richard V., Martin L., Rejean B., et al. The desulfitobacterium genus. FEMS Microbiology Reviews, 2006,30(5):706-733
[17]  董玲玲, 吴锦华, 吴海珍,等. 硝基苯厌氧生物降解过程中Fe0的促进作用.环境化学, 2005,24(6):643-646 Dong L. L., Wu J. Ha, Wu H. Z., et al. The accelerative effect of Fe0 on anaerobic degradation nitrobenzene. Environmental Chemistry, 2005,24(6):643-646(in Chinese)
[18]  Clark C. J., Rao P. S. C., Annable M. D. Degradation of perchloroethylene in cosolvent solutions by zero-valent iron. Journal of Hazardous Materials B, 2003,96(1):65-78
[19]  徐桂英.金属微生物腐蚀的电化学机理.辽宁师范大学学报,1994,17(2):173-176 Xu G. Y. The electrochemicay corrosion mechanism of microorganism. Journal of Liaoning Normal University, 1994,17(2):173-176(in Chinese)
[20]  龙荷云,等.循环冷却水处理.南京:江苏科学技术出版社,2001

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