高级搜索

水产养殖对水生生态系统中汞甲基化影响研究进展

downloadPDF

上一篇

下一篇

闫海鱼, 冯彩艳. 水产养殖对水生生态系统中汞甲基化影响研究进展[J]. 环境化学, 2012, 31(11): 1782-1786.
引用本文: 闫海鱼, 冯彩艳. 水产养殖对水生生态系统中汞甲基化影响研究进展[J]. 环境化学, 2012, 31(11): 1782-1786.
shu
YAN Haiyu, FENG Caiyan. Resesrcher necessity and advances about influence on methlylation of mercury in aquatic ecosystem from the aquaculture[J]. Environmental Chemistry, 2012, 31(11): 1782-1786.
Citation: YAN Haiyu, FENG Caiyan. Resesrcher necessity and advances about influence on methlylation of mercury in aquatic ecosystem from the aquaculture[J]. Environmental Chemistry, 2012, 31(11): 1782-1786.
shu

水产养殖对水生生态系统中汞甲基化影响研究进展

  • 1.

    中国科学院地球化学研究所, 环境地球化学国家重点实验室, 贵阳, 550002;

  • 2.

    中国科学院大学, 北京, 100049

  • 基金项目:

    国家自然科学基金项目(40973083,40803036,41273099)资助.

Resesrcher necessity and advances about influence on methlylation of mercury in aquatic ecosystem from the aquaculture

  • 1.

    Geochemistry of Insititue, the Chinese Academy of Sciences, Guiyang, 550002, China;

  • 2.

    University of Chinese Academy of Sciences, Beijing, 100049, China

  • Fund Project:

  • 摘要: 水产养殖造成的水体富营养化不仅导致有机质增加,而且致使很多水体理化参数发生变化,包括水中溶解氧下降、沉积物中有机质和硫酸盐、硫化氢的增加、pH值的下降、生物和微生物群落的破坏等.然而,目前国内外在这方面的研究极少,水产养殖对水体汞甲基化的影响尚不清楚,对其进行深入的研究,并提出合理利用和开发水资源的科学建议具有重要的现实意义.
    Abstract: Aquaculture can lead to eutriophication and High organic matter in aquatic system. At the same time,multipile physical and chemical water paramates will change such as dissolve oxgen and pH decrease, sufide(sulfate) and organic matter increase in sediment, and destroying biological community composition, which affact by using the fish pharmaceutical as well excreta input. The efflunce on methylation of mercury in aqautic system from aquaculture has not well understanding, and few reseach is done till now. Therefore, it is very necessary for reasonablly utilizing and developing reservoir resources in future management.
  • 加载中
  • [1] ATSDR (Agency for Toxic Substances Disease Registry). Toxicological profile for mercury. ATSDR [M]. Atlanta, GA. 1997, (DRAFT UPDATE).
    [2] Smith F A, Sharma R P, Lynn R I, et al. Mercury and selected pesticide levels in fish and wildlife of Utah: I. Levels of mercury, DDT, DDE, dieldrin and PCB in fish [J]. Environ Toxicol Chem, 1974, 12: 218-223
    [3] Abernathy A R, Cumbie P M. Mercury accumulation by largemouth bass (Micropterussalmoides) in recently impounded reservoirs [J]. Environm Cont Tox, 1977, 17: 595-602
    [4] Cox J A, Carnahan J, Dinuzio J, et al. Source of mercury in fish in new impoundments [J]. Environm Cont Tox, 1979, 23: 779-783
    [5] Hecky R E, Ramsey D J, Bodsly R A, et al. Increased methylmercury contamination in fish in newly formed freshwater reservoirs // Suzuki T. Advances in mercury toxicology[M]. New York:Plenum Press,1991
    [6] Yingcharoen D, Bodaly R A. Elevated mercury levels in fish resulting from reservoir flooding in Thailand [J]. Asian Fisheries Science, 1993, 6:73-80
    [7] Kelly C A, Rudd J W M, Bodaly R A, et al. Increases in fluxes of greenhouse gases and methylmercury following flooding of an experimental reservoir [J]. Environ Sci Technol, 1997, 31: 1334-1344
    [8] Tremblay A, Lucotte M, Schetagne R. Total mercury and methylmercury accumulation in zooplankton of hydroelectric reservoirs in northern Québec (Canada) [J]. Sci Tot Environ, 1998, 213: 307-315
    [9] Tremblay A, Cloutier L, Lucotte M. Total mercury and methylmercury fluxes via emerging insects in recently flooded hydroelectric reservoirs and a natural lake [J]. Sci Tot Environ, 1998, 219: 209-221
    [10] Tremblay A, Lucotte M. Accumulation of total mercury and methylmercury in insect larvae of hydroelectric reservoirs [J]. Can J Fish Aquat Sci, 1997, 54: 832-841
    [11] Heyes A, Moore T R, Rudd J W M, et al. Methylmercury in pristine and impounded boreal peatlands, experimental lakes area, Qntario [J]. Can J Fish Aquat Sci, 2000, 57(11): 2211-2222
    [12] Hecky R E, Bodaly R A, Strange N E, et al. Mercury bioaccumulation in yellow perch in limnocorrals simulating the effects of reservoir creation. Canadian Data Report of Fisheries and Aquatic Sciences No. 628, 1987:1-174
    [13] Yingcharoen D R E, Bodaly R A. Elevated mercury levels in fish resulting from reservoir flooding in Tailand [J]. Asian Fish Sci, 1993, 6:73-80
    [14] Jackson T A. The mercury problem in recently formed reservoirs of northern Manitoba (Canada): effects of impoundment and other factors on the production of methylmercury by microorganisms in sediments [J]. Can J Fish Aquat Sci, 1988, 45: 97-121
    [15] Bodaly R A, Hecky R E, Fudge R J P. Increases in fish mercury levels in lakes flooded by the Churchill River diversion, northern Manitoba [J]. Can J Fish Aquat Sci, 1984, 41: 682-691
    [16] Jackson T A. Biological and environmental control of mercury accumulation by fish in lakes and reservoirs of northern Manitoba, Canada [J]. Can J Fish Aquat Sci, 1991, 48: 2449-2470
    [17] Verdon R, Brouard D, Demers C, et al. Mercury evolution 1978-1988 in fishes of the La grande hydroeletric complex, Quebec Canada [J]. Water Air Soil Pollut, 1991, 56: 405-417
    [18] Bodaly R, Jansen W, Majewski A, et al. Postimpoundment time course of increased mercury concentrations in fish in hydroelectric reservoirs of Northern Manitoba, Canada[J]. Archives of Environmental Contamination and Toxicology, 2007, 53(3): 379-389
    [19] Friedl G, Wüest A. Disrupting biogeochemical cycles-Consequences of damming [J]. Aquat Sci, 2002, 64:55-65
    [20] Bodaly R A, St.Louis V L, Paterson M J, et al. Bioaccumulation of mercury in the aquatic food chain in newly flooded areas // Sigel A, Sigel H. Metal ions in biological systems: Mercury and it effects on the environment and biology[M]. New York: Marcel Dekker, 1997, 268-275
    [21] Schetagne R, Verdon R. Post-impoundment evolution of fish mercury levels at the La Grande complex, Québec, Canada from 1978 to 1996//Lucotte M, Schetagne R, Therien N, et al. Mercury in the biogeochemical cycle: natural environments and hydroelectric reservoirs of northern Québec[M]. Berlin: Springer, 1999: 253-238
    [22] Feng X, Jiang H, Qiu G, et al. Geochemical processes of mercury in Wujiangdu and Dongfeng reservoirs, Guizhou, China[J]. Environmental Pollution, 2009, 157(11): 2970-2984
    [23] 蒋红梅. 水库对乌江河流汞生物地球化学循环的影响[D]. 北京:中国科学院研究生院博士学位论文,2005
    [24] Olson, Cooper. Comparison of aerobic and anaerobic methylation of mercuric chloride by San Francisco Bay sediments[J]. Water Research, 1976, 10(2):113-116
    [25] Compeau G, Bartha R. Effect of sea salt anions on the formation and stability of methymercury[J]. Bull Environ Contam Toxicol, 1983, 31:486
    [26] Liu B, Yan H, Wang C, et al. Insights into low fish mercury bioaccumulation in a mercury-contaminated reservoir, Guizhou, China[J]. Environmental Pollution, 2012, 160: 109-117
    [27] King J, Michele H, Fu T, et al. Mercury removal, methylmercury formation, and sulfate-reducing bacteria profiles in wetland mesocosms[J]. Chemosphere, 2002, 46(6): 859-870
    [28] Kotnik J, Horvat M, Jereb V. Modelling of mercury geochemical cycle in Lake Velenje, Slovenia[J]. Environmental Modelling & Software, 2002, 17(7):593-611
    [29] Ullrich S M, Tanton T W, Abdrashitova S A, et al. Mercury in the aquatic environment: A review of factors affecting methylation[J]. Critical Reviews in Environmental Science and Technology, 2001, 31(3): 241-293
    [30] Bravo A G, Dominik J, Bouchet S, et al. Methylmercury concentrations and sulphate-reducing bacteria in freshwater sediments contaminated by a chlor-alkali plant: Babeni reservoir, Romania[J]. Recent Advances in Environment, Ecosystems and Development, 2009: 196-200
    [31] 涂杰锋,罗钦,伍云卿,等.福建水产饲料重金属污染研究[J]. 中国农学通报, 2011, 27(29): 76-79
    [32] Brooks K M, Stierns A R, Backman C. Seven year remediation study at the Carrie Bay Atlantic salmon (Salmo salar) farm in the Broughton Archipelago[J]. British Columbia Canada Aquaculture, 2004, 239(1-4): 81-123
    [33] Brooks K M, Stierns A R, Mahnken C V W, et al. Chemical and biological remediation of the benthos near Atlantic salmon farms[J]. Aquaculture,2003: 219, 255
    [34] Debruyn A M H, Trudel M, Eyding N, et al. Ecosystemic effects of salmon farming increase mercury contamination in wild fish[J]. Environ Sci Technol, 2006, 40:3489-3493
    [35] Englehaupt E. Farming the deep blue sea[J]. Environ Sci Technol, 2007, 41: 4188-4191
    [36] FAO (Food and Agriculture Organization of the United Nations). State of World Aquaculture 2006. FAO Fisheries Technical Paper, No. 500. Rome, FAO, 2006: 134
    [37] FAO (Food and Agriculture Organization of the United Nations). Fishery and Aquaculture Country Profile, United States of America. 2007a
    [38] FAO (Food and Agriculture Organization of the United Nations). Aquaculture-new opportunities and a cause for hope. 2007b
    [39] 侃计.2007年全国水产养殖面积为5633.21千ha[J]. 现代渔业信息,2008,23(8): 29
    [40] 刘潇波,郑志勇,高殿森. 网箱养鱼对水环境影响研究及展望[J]. 北方环境,2004, 29(4):5-25
    [41] 范林君.网箱养鱼对红光水库和百丈水库水质影响的研究[J]. 重庆:西南大学硕士学位论文,2006
    [42] 陈苏维,朱文东.网箱养殖对水环境的影响及解决方法[J]. 安徽农业科学,2007,35(30):9538-9540
    [43] 陈小江.三峡库区万州段网箱养殖区水化学和初级生产力研究[J]. 重庆:西南大学硕士学位论文,2007
    [44] 余方平,孙忠,郭远明,等. 三门湾健跳网箱养鱼区营养盐的变化及水质现状评价[J]. 浙江海洋学院学报, 2006, 25(4): 402-406
    [45]
    [46] 张明亮. 胶州湾贝类养殖容量研究与分析[J]. 青岛:国家海洋局第一海洋研究所硕士学位论文, 2008
    [47] 刘义峰,吴桑云,孙书贤,等. 胶州湾、莱州湾潮间带沉积物污染比较[J].海岸工程,2009, 28(2): 61-68
    [48] He Tianrong, Feng Xinbin, Guo Yanna, et al. Distribution and speciation of mercury in Hongfeng Reservoir, Guizhou, China[J]. Chinese Journal of Geochemistry, China J Geochem, 2008, 27:97-103
    [49] Meng B, Feng X, Chen C, et al. Influence of eutrophication on the distribution of total mercury and methylmercury in hydroelectric reservoirs[J]. Journal of Environmental Quality, 2010, 39 (5): 1624-1635
    [50] 冯彩艳,闫海鱼,俞奔,等. 网箱养鱼对水库水体甲基汞地球化学行为影响探讨[J].生态学杂志,2012, 31(6): 1-9
    [51] Liang Peng S D D, Wu Sheng-Chun, Shi Jian-Bo, et al. The influence of mariculture on mercury distribution in sediments and fish around Hong Kong and adjacent mainland China waters[J]. Chemosphere,2011, 82: 1038-1043
    [52] Gray J E, Hines M E. Biogeochemical mercury methylation influenced by reservoir eutrophication, Salmon Falls Creek Reservoir, Idaho, USA[J]. Chemical Geology, 2009, 258(3-4):157-167
  • 加载中
WeChat 点击查看大图
计量
  • 文章访问数:  1143
  • HTML全文浏览数:  1080
  • PDF下载数:  511
  • 施引文献:  0
出版历程
  • 收稿日期:  2012-01-14
闫海鱼, 冯彩艳. 水产养殖对水生生态系统中汞甲基化影响研究进展[J]. 环境化学, 2012, 31(11): 1782-1786.
引用本文: 闫海鱼, 冯彩艳. 水产养殖对水生生态系统中汞甲基化影响研究进展[J]. 环境化学, 2012, 31(11): 1782-1786.
shu
YAN Haiyu, FENG Caiyan. Resesrcher necessity and advances about influence on methlylation of mercury in aquatic ecosystem from the aquaculture[J]. Environmental Chemistry, 2012, 31(11): 1782-1786.
Citation: YAN Haiyu, FENG Caiyan. Resesrcher necessity and advances about influence on methlylation of mercury in aquatic ecosystem from the aquaculture[J]. Environmental Chemistry, 2012, 31(11): 1782-1786.
shu

水产养殖对水生生态系统中汞甲基化影响研究进展

  • 1.  中国科学院地球化学研究所, 环境地球化学国家重点实验室, 贵阳, 550002;
  • 2.  中国科学院大学, 北京, 100049
  • 收稿日期:  2012-01-14
基金项目:

国家自然科学基金项目(40973083,40803036,41273099)资助.

摘要: 水产养殖造成的水体富营养化不仅导致有机质增加,而且致使很多水体理化参数发生变化,包括水中溶解氧下降、沉积物中有机质和硫酸盐、硫化氢的增加、pH值的下降、生物和微生物群落的破坏等.然而,目前国内外在这方面的研究极少,水产养殖对水体汞甲基化的影响尚不清楚,对其进行深入的研究,并提出合理利用和开发水资源的科学建议具有重要的现实意义.

English Abstract

    全文HTML

参考文献 (52)

返回顶部

目录

/

返回文章
返回

Copyright © 2019 中国科学院生态环境研究中心