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Sorption – desorption of imidacloprid insecticide on Indian soils of five different locations

Year 2013, Volume: 2 Issue: 2, 107 - 113, 01.06.2013

Abstract

Sorption-desorption processes govern the movement of all chemicals including pesticides in soils.  The present investigation was undertaken to study the sorption-desorption of imidacloprid, using a batch method, on soils of five different location of India. Sorption data were fitted to Freundlich isotherm. The log K value was the highest for loam type soil (1.830) and the lowest for clay type soil (1.661). The value of 1/n was the maximum for silt loam soil (0.909) but minimum for loam soil (0.723). Simple correlation analysis indicated that among soil properties only electrical conductivity showed a higher but marginally non-significant negative correlation with log K (r = -0.826) indicating that higher concentration of solutes solutes are conducive to low sorption capacity of soil. The desorption data conformed to two surfaces Freundlich desorption isotherm. The values of 1/n1' corresponding to easily desorbed fraction of imidacloprid showed significant negative correlation with soil pH (r = -0.886, significant at p ≤0.05) but significant positive correlation with clay content (r = 0.980, significant at p ≤0.01). The desorption index for easily desorbed fraction of imidacloprid (n1’/n) also had significant negative correlation with soil pH (r = 0.953, significant at p ≤0.05). From cumulative desorption data, it appeared that bioavailability of imidacloprid would be lower in neutral soil than acidic or alkaline soils.

References

  • Barriuso, E., Baer, U., Calvet, R., 1992. Dissolved organic matter and sorption desorption of dimefuron, atrazine and carbetamide by soils. Journal of Environmental Quality 21: 359-367.
  • Bauder, T., Waskom, R., Pearson, R., 2010. Best Management Practices for Agricultural Pesticide Use to Protect Water Quality. Bulletin #XCM-177, page-01.
  • Cox, L., Koskinen, W.C., Yen, P., 1998. Influence of soil properties on sorption‐desorption of imidacloprid. Journal of Environmental Science and Health, Part B: Pesticides, Food, Contaminants, and Agricultural Wastes 33(2): 123-134.
  • Elbert, A., Becker, B., Hartwig, J., Erdelen, C., 1991. Imidacloprid-a new systemic insecticide. Pflanzenschutz Nachricten Bayer, 44: 113-136.
  • Fernandez-Bayo, J.D., Nogales, R., Romero, E., 2007. Improved retention of imidacloprid (Confidor) in soils by adding vermicompost from spent grape marc. Science of the Total Environment 378(1-2): 95-100.
  • Flores-Cespedes, F., Gonzalez, E.P., Fernandez, M.P., Villafranca, M.S., Socias, M.V., Urena, M.D.A., 2002. Effects of dissolved organic carbon on sorption and mobility of imidacloprid in soil. Journal of Environmental Quality 31: 880-888.
  • Gao, J.P., Maguhn, J., Spitzauer, P., Kettrup, A., 1998. Sorption of pesticides in the sediment of the Teufelesweiher pond (southern Germany). I: equilibrium assessments, effect of organic carbon content and pH. Water Research 32(5): 1662-1672.
  • Huang, P.M., Mckercher, R.B., 1984. Components and particle size fractions involved in atrazine adsorption by soils. Soil Science 138: 20-24.
  • Jackson, M.L., 1958. Soil Chemical Analysis, Prentice hall, New York, N.Y., USA. pp.153-158.
  • Koskinen, W.C., Harper, S.S., 1990. The retention process: mechanisms. In H.H.Cheng (ed.) Pesticides in the Soil Environment: Processes, Impacts and Modeling. SSSA,Madison, WI, pp:51-77.
  • Liu, W., Zheng, W., Gan, J., 2002. Competitive sorption between imidacloprid and imidacloprid-urea on soil clay minerals and humic acids. Journal of Agricultural and Food Chemistry 50(23): 6823-6827.
  • OECD, 2000. OECD guidelines for testing of chemicals, June 2000: Section 106.
  • Page, A.L., 1982. Methods of Soil Analysis: Chemical and Microbiological Properties. Vol. 9. Soil Science Society of America. Madison, WI.
  • Ramakrishnan, R., Suiter, D.R., Nakatsu,C.H., Bennett, G.W., 2000. Feeding inhibition and mortality in Reticulitermes flavipes (Isoptera:Rhinotermitidae) after exposure to imidacloprid treated soils. Journal of Economic Entomology 93(2): 422-428.
  • Torrents, A., Jayasundera, S., 1997. The sorption of nonionic pesticides onto clays and the influence of natural organic carbon. Chemosphere 35(7):1549–1565.
  • www.main.co.il. Biological Data Sheet Kohinor (Imidacloprid). Makhteshim Agan Industries Ltd. Israel. pp. 1-10.
Year 2013, Volume: 2 Issue: 2, 107 - 113, 01.06.2013

Abstract

References

  • Barriuso, E., Baer, U., Calvet, R., 1992. Dissolved organic matter and sorption desorption of dimefuron, atrazine and carbetamide by soils. Journal of Environmental Quality 21: 359-367.
  • Bauder, T., Waskom, R., Pearson, R., 2010. Best Management Practices for Agricultural Pesticide Use to Protect Water Quality. Bulletin #XCM-177, page-01.
  • Cox, L., Koskinen, W.C., Yen, P., 1998. Influence of soil properties on sorption‐desorption of imidacloprid. Journal of Environmental Science and Health, Part B: Pesticides, Food, Contaminants, and Agricultural Wastes 33(2): 123-134.
  • Elbert, A., Becker, B., Hartwig, J., Erdelen, C., 1991. Imidacloprid-a new systemic insecticide. Pflanzenschutz Nachricten Bayer, 44: 113-136.
  • Fernandez-Bayo, J.D., Nogales, R., Romero, E., 2007. Improved retention of imidacloprid (Confidor) in soils by adding vermicompost from spent grape marc. Science of the Total Environment 378(1-2): 95-100.
  • Flores-Cespedes, F., Gonzalez, E.P., Fernandez, M.P., Villafranca, M.S., Socias, M.V., Urena, M.D.A., 2002. Effects of dissolved organic carbon on sorption and mobility of imidacloprid in soil. Journal of Environmental Quality 31: 880-888.
  • Gao, J.P., Maguhn, J., Spitzauer, P., Kettrup, A., 1998. Sorption of pesticides in the sediment of the Teufelesweiher pond (southern Germany). I: equilibrium assessments, effect of organic carbon content and pH. Water Research 32(5): 1662-1672.
  • Huang, P.M., Mckercher, R.B., 1984. Components and particle size fractions involved in atrazine adsorption by soils. Soil Science 138: 20-24.
  • Jackson, M.L., 1958. Soil Chemical Analysis, Prentice hall, New York, N.Y., USA. pp.153-158.
  • Koskinen, W.C., Harper, S.S., 1990. The retention process: mechanisms. In H.H.Cheng (ed.) Pesticides in the Soil Environment: Processes, Impacts and Modeling. SSSA,Madison, WI, pp:51-77.
  • Liu, W., Zheng, W., Gan, J., 2002. Competitive sorption between imidacloprid and imidacloprid-urea on soil clay minerals and humic acids. Journal of Agricultural and Food Chemistry 50(23): 6823-6827.
  • OECD, 2000. OECD guidelines for testing of chemicals, June 2000: Section 106.
  • Page, A.L., 1982. Methods of Soil Analysis: Chemical and Microbiological Properties. Vol. 9. Soil Science Society of America. Madison, WI.
  • Ramakrishnan, R., Suiter, D.R., Nakatsu,C.H., Bennett, G.W., 2000. Feeding inhibition and mortality in Reticulitermes flavipes (Isoptera:Rhinotermitidae) after exposure to imidacloprid treated soils. Journal of Economic Entomology 93(2): 422-428.
  • Torrents, A., Jayasundera, S., 1997. The sorption of nonionic pesticides onto clays and the influence of natural organic carbon. Chemosphere 35(7):1549–1565.
  • www.main.co.il. Biological Data Sheet Kohinor (Imidacloprid). Makhteshim Agan Industries Ltd. Israel. pp. 1-10.
There are 16 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Shailendra Singh Chauhan This is me

Anjana Srivastava This is me

Prakash Chandra Srivastava This is me

Ankita Verma This is me

Publication Date June 1, 2013
Published in Issue Year 2013 Volume: 2 Issue: 2

Cite

APA Chauhan, S. S., Srivastava, A., Srivastava, P. C., Verma, A. (2013). Sorption – desorption of imidacloprid insecticide on Indian soils of five different locations. Eurasian Journal of Soil Science, 2(2), 107-113.