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^(14)C-氯氰菊酯农药在“微宇”环境中的迁移、归宿 被引量:1

The Transport and Fate of ^(14)C-cypermethrin in A Microcosm under the Laboratory Conditions.
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摘要 本文在“微宇”环境中研究^(14)C-氯氰菊酯在玉米-土壤-土壤动物相间的质量平衡、吸收、结合残留、迁移和转化规律。实验结果表明,植物通过根部从土壤中吸收少量氯氰菊酯,并通过叶脉输导,但向上输导能力差,无内吸作用。它在土壤中性质较稳定,被动、植物吸收的药剂,在植物体内主要转化为结合态;在动物中则主要为代谢作用。它在土壤中以酯链断裂为主要降解路线,其次为4′-位置上羟化,再经土壤甲基化作用生成4′-甲氧基代谢物。 The aim of the experiments is to study mass balance of 14C^cypermethrin in a close ecosystem by observing metabolism, degradation and distribution of the pesticide. The microcosm was set up in a 30 cm-desiccator with 15 one-week-old maize plants and 15 earthworms (Eiscnia foetida) in the sandy loam soil containing 5.5ppm pure 14C-cypermethrin.The results indicated that cypermethrin residues was absorbed in the maize roots, but very little was to be migrated to the leaves. After two weeks, the mafor product in the maize plants was the bound compounds which contained 81.81%; the armount of metabolic products in the earthworms was 72.40%; parent of cyper-methrin in soil 68.74%. In soil main product 3-phenoxy-benzaldehyde was degraded by splitting of chain easter and 4'-methoxy-compound was formed by hydroxylation and methoxylation at 4'-carbon atom.
作者 周振惠 R.Viswanathan
机构地区 中国科学院上海昆虫研究所 西德GSF.生态化学研究所
出处 《环境科学》 EI CAS CSSCI CSCD 北大核心 1990年第5期2-6,共5页 Environmental Science
关键词 农药 微宇环境 迁移 归宿 结合残留 14C-cypermethrin, fate, transport, soil, plant.
分类号 X592.032.3 [环境科学与工程—环境工程]
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参考文献1

  • 1周振惠,中国环境科学,1986年,6卷,31页

同被引文献23

  • 1范桂枝,蔡庆生.植物对大气CO_2浓度升高的光合适应机理[J].植物学通报,2005,22(4):486-493. 被引量:22
  • 2张颖,王金春,薛庆林,马德伟,孟静.CO_2施肥对光合作用及相关生理过程的影响[J].中国农学通报,2006,22(2):212-215. 被引量:12
  • 3Oh T H.Carbon capture and storage potential in coal-fired plant in Malaysia-A review[J].Renewable and Sustainable Energy Reviews,2010,14(9):2697-2709.
  • 4Hansson A,Bryngelsson M.Expert opinions on carbon dioxide capture and storage-A framing of uncertainties and possibilities[J].Energy Policy,2009,37(6):2273-2282.
  • 5Jaffrin A,Bentounes N,Joan A M,et al.Landfill Biogas for heating greenhouses and providing carbon dioxide supplement for plant growth[J].Biosystems Engineering,2003,86(1):113-123.
  • 6Glick B R.Using soil bacteria to facilitate phytoremediation[J].Biotechnology Advances,2010,28(3):367-374.
  • 7Gerhardt K E,Huang X D,Glick B R,et al.Phytoremediation and rhizoremediation of organic soil contaminants:potential and challenges[J].Plant Science,2009,176(1):20-30.
  • 8Kuuskra V A.Review and evaluation of the CO2 capture project by the technology advisory board:carbon dioxide capture for storage in deep geologic formations-results from the CO2 capture project Ⅰ[M].UK:Elsevier,2005.
  • 9Johnsona D L,Maguirea K L,Andersonb D R,et al.Enhanced dissipation of chrysene in planted soil:the impact of a rhizobial inoculum[J].Soil Biology & Biochemistry,2004,36(1):33-38.
  • 10Abhilash P C,Jamil S,Singh N.Transgenic plants for enhanced biodegradation and phytoremediation of organic xenobiotics[J].Biotechnology Advances,2009,27(4):474-488.

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环境科学
1990年 第5期

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