OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

湖泊科学 2013

太湖不同形态异味物质含量、相互关系及其与环境因子关系的探讨

DOI: 10.18307/2013.0105

齐敏,孙小雪,邓绪伟,陈隽,谢平

Keywords: 太湖,溶解态,结合态,异味化合物,相互关系,环境因子

Full-Text Cite this paper Add to My Lib

Abstract:

根据2009年6月到2010年5月太湖水样中溶解态和结合态异味化合物(2-甲基异茨醇(MIB)、土嗅素(GEO)、β-环柠檬醛、β-紫罗兰酮)的月间采样分析结果,综合考虑各种环境因子以及蓝藻种属,探讨了溶解态和结合态异味化合物之间的关系以及影响太湖中异味化合物的主要环境因子.结果表明溶解态MIB和结合态β-环柠檬醛、β-紫罗兰酮是研究期间湖水中的主要异味化合物,这些物质对于太湖水体发生异味具有较大贡献或较大潜在贡献.通过本文研究和对以往文献讨论推测,太湖中溶解态和结合态异味化合物相关关系较弱的原因可能是,异味化合物生产和释放速率的变化、微生物降解、光解、吸附和挥发等.同时发现微囊藻和叶绿素a与太湖异味化合物关系密切.蓝藻水华对于太湖异味化合物的发生具有重要影响,控制蓝藻水华发生的关键是控制或减缓太湖异味问题.

References

[1]	Smith JL,Boyer GL,Zimba PV. A review of cyanobacterial odorous and bioactive metabolites: impacts and management alternatives in aquaculture. Aquaculture,2008,280(1/2/3/4): 5-20.
[2]	徐盈,黎雯,吴文忠等. 东湖富营养水体中藻菌异味性次生代谢产物的研究. 生态学报,1 999, 19(2): 212-216.
[3]	黄显怀. 巢湖水体异味产生的原因及其治理对策探讨. 安徽建筑工业学院学报: 自然科学版,1 994,2 (1): 5-8.
[4]	Li L,Wan N,Gan NQ et al. Annual dynamics and origins of the odorous compounds in the pilot experimental area of Lake Dianchi,China. Water Science and Technology,2007,55(5): 43-50.
[5]	Watson SB. Cyanobacterial and eukaryotic algal odour compounds: signals or by-products? A review of their biological activity. Phycologia,2003,42(4): 332-350.
[6]	Chen J,Xie P,Ma ZM et al. A systematic study on spatial and seasonal patterns of eight taste and odor compounds with relation to various biotic and abiotic parameters in Gonghu Bay of Lake Taihu,China. Science of the Total Environment, 2010,409(2): 314-325.
[7]	Tsuchiya Y,Matsumoto A,Okamoto T. Volatile metabolites produced by actinomycetes isolated from Lake Tairo at Miyakejima. Yakugaku Zasshi-Journal of the Pharmaceutical Society of Japan,1978,98(4): 545-550.
[8]	Kikuchi T,Kadota S,Suehara H et al. Odorous metabolites of a fungus,Chaetomium globosum Kinze ex Fr. identification of geosmin,musty-smelling compound. Chemical & Pharmaceutical Bulletin,1981,29(6): 1782-1784.
[9]	Yamamoto Y,Tanaka K,Komori N. Volatile compounds excreted by myxobacteria isolated from lake water and sediments. Japanese Journal of Limnology,1994,55(4): 241-245.
[10]	Mallevialle J,Suffet IH. Identification and treatment of tastes and odors in drinking water. Denver,CO: American Water Works Association Research Foundation/Lyonnaise des Eaux,AWWA;1987. p. 118. AWWARF Report 1987.
[11]	Young W,Horth H,Crane R et al. Taste and odour threshold concentrations of potential potable water contaminants. Water Research,1996,30(2): 331-340.
[12]	更多...
[13]	胡鸿钧,魏印心. 中国水产藻类——系统、分类及生态. 北京: 科学出版社, 2006.
[14]	Niu Y,Shen H,Chen J et al. Phytoplankton community succession shaping bacterioplankton community composition in Lake Taihu,China. Water Research,2011,45: 4169-4182.
[15]	Deng XW,Liang GD,Chen J et al. Simultaneous determination of eight common odors in natural water body using automatic purge and trap coupled to gas chromatography with mass spectrometry. Journal of Chromatography A,2011,1218 (24): 3791-3798.
[16]	Deng XW,Xie P,Qi M et al. Microwave-assisted purge-and-trap extraction device coupled with gas chromatography and mass spectrometry for the determination of five predominant odors in sediment,fish tissues,and algal cells. Journal of Chromatography A,2012,1219: 75-82.
[17]	Izaguirre G,Hwang CJ,Krasner SW. Investigations into the source of 2-methylisoborneol in Lake Perris,California. In: Proceedings of 11th Annual Water Quality Technology Conference,4-7 December. 1983,Norfolk VA,USA. American Water Works Association,Denver,CO.
[18]	李林. 淡水水体中藻源异味化合物的分布、动态变化与降解研究[学位论文]. 武汉: 中国科学院水生生物研究所, 2005.
[19]	Westerhoff P,Rodriguez-Hernandez M,Baker L et al. Seasonal occurrence and degradation of 2-methylisoborneol in water supply reservoirs. Water Research,2005,39(20): 4899-4912.
[20]	Danglot C,Amar R,Viagines R. Ability of bacillus to degrade geosmin. Water Science and Technology,1983,15(6/7): 291-299.
[21]	Ishida H,Miyaji Y. Biodegradation of 2-methylisoborneol by oligotrophic bacterium isolated from a eutrophied lake. Water Science and Technology,1992,25(2): 269-276.
[22]	Oikawa E,Shimizu A,Ishibashi Y. 2-Methylisoborneol degradation by the cam operon from pseudomonas-putida Pgg1. Water Science and Technology,1995,31(11): 79-86.
[23]	Sugiura N,Nishimura O,Inamori Y et al. Grazing characteristics of musty-odor-compound-producing Phormidium tenue by a microflagellate,Monas guttula. Water Research,1997,31(11): 2792-2796.
[24]	Tanaka A,Oritani T,Uehara F et al. Biodegradation of a musty odour component,2-methylisoborneol. Water Research, 1996,30(3): 759-761.
[25]	李林,宋立荣,陈伟等. 淡水藻源异味化合物的光降解和光催化降解研究. 中国给水排水,2007,23 (13): 102-105.
[26]	Rimando AM,Schrader KK. Off-flavors in aquaculture. Washington,DC: American Chemical Society,2003: 1-13.
[27]	范成新,张路,秦伯强等. 风浪作用下太湖悬浮态颗粒物中磷的动态释放估算. 中国科学: D 辑,2003,33(8): 760-768.
[28]	Watson SB,Ridal J. Periphyton: a primary source of widespread and severe taste and odour. Water Science and Technology, 2002,49(9): 33-39.
[29]	Xu LP,Xiong BX,Pan Y et al. Relationship between concentrations of odorous compounds and biomass of phytoplankton and actinomycetes in freshwater ponds of Beijing,China. Aquaculture International,2010,18(3): 245-254.
[30]	Dzialowski AR,Smith VH,Huggins DG et al. Development of predictive models for geosmin-related taste and odor in Kansas,USA,drinking water reservoirs. Water Research,2009,43(11): 2829-2840.
[31]	Peter A,K？ster O,Schildknecht A et al. Occurrence of dissolved and paticle-bound taste and odor compounds in Swiss lake waters. Water Research,2009,43(8): 2191-2200.
[32]	Tung SC,Lin TF,Liu CL et al. The effect of oxidants on 2-MIB concentration with the presence of cyanobacteria. Water Science and Technology,2004,49(9): 281-288.
[33]	Yang M,Yu JW,Li ZL et al. Taihu Lake not to blame for Wuxi\'s woes. Science,2008,319(5860): 158.
[34]	金相灿,屠清瑛. 湖泊富营养化调查规范. 北京: 中国环境科学出版社, 1990: 229-230.
[35]	Baumann FJ. Dichromate reflux chemical oxygen demand-Proposed method for chloride correction in highly saline wastes. Analytical Chemistry,1974,46: 1336-1338.
[36]	Lorenzen CJ. Determination of chlorophyll and pheo-pigments: spectrophotometric equations. Limnology and Oceanography, 1967,12: 343-346.
[37]	Guo L. Doing battle with the green monster of Taihu Lake. Science,2007,317: 1166.
[38]	Smith JL,Boyer GL,Zimba PV. A review of cyanobacterial odorous and bioactive metabolites: impacts and management alternatives in aquaculture. Aquaculture,2008,280(1/2/3/4): 5-20.
[39]	Zimba PV,Grimm CC. A synoptic survey of musty/muddy odor metabolites and microcystin toxin occurrence and concentration in southeastern USA channel catfish(Ictalurus punctatus Ralfinesque) production ponds. Aquaculture,2003,218 (1/2/3/4): 81-87.
[40]	Huang WJ,Lai CH,Cheng YL. Evaluation of extracellular products and mutagenicity in cyanobacteria cultures separated from a eutrophic reservoir. Science of the Total Environment,2007,377(2/3): 214-223.
[41]	Huang WJ,Cheng YL,Cheng BL. Ozonation byproducts and determination of extracellular release in freshwater algae and cyanobacteria. Environmental Engineering Science,2008,25(2): 139-151.
[42]	Crocker KM,Ondrusek ME,Petty RL et al. Dimethylsulfide,algal pigments and light in an Antarctic Phaeocysis sp. bloom. Marine Biology,1995,124: 335-340.
[43]	Davies JM,Roxborough M,Mazumder A. Origins and implications of drinking water odours in lakes and reservoirs of British Columbia,Canada. Water Research,2004,38: 1900-1910.
[44]	Satchwill T,Watson SB,Dixon E. Odourous algal-derived alkenes: differences in stability and treatment responses in drinking water. Water Science and Technology,2007,55(5): 95-102.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133