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Języki publikacji
Abstrakty
The aim of the studies was to determine the influence of copper and zinc contamination on clopyralid dissipation in soil. The experiment was carried out in laboratory conditions (plant growth chamber). Clopyralid was applied to three different soils [similar textures, pH, organic carbon content and contrasting copper and zinc content: soil natural contaminated with Cu and Zn (S1), soil with natural low Cu and Zn concentration (S2) and soil S21 prepared in the laboratory (S2 soil additionally contaminated with Cu and Zn salts in the amounts equivalent to contamination level of S1 soil)]. Soil samples were taken for analyses for 1 hour (initial concentration) and 2, 4, 8, 16, 32, 64 and 96 days after treatment. Clopyralid residue was analysed using GC/ECD (gas chromatography with electron capture detector). Good linearity was found between logarithmic concentration of clopyralid residues and time. The differences in Cu and Zn content influenced the clopyralid decay in soil. The values of DT50 obtained in the experiment ranged from 21 to 27 days. A high concentration of Cu and Zn in soil slowed down clopyralid degradation (the DT50 value was higher – 25–27 days).
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
38--42
Opis fizyczny
Bibliogr. 26 poz., tab., rys.
Twórcy
autor
- Institute of Soil Science and Plant Cultivation - State Research Institute, Department of Weed Science and Tillage Systems, Orzechowa 61, 50-540 Wrocław, Poland
autor
- Institute of Soil Science and Plant Cultivation - State Research Institute, Department of Weed Science and Tillage Systems, Orzechowa 61, 50-540 Wrocław, Poland
Bibliografia
- 1. Allen R., Walker A. 1987. Influence of soil properties on the degradation rates of metamitron, metazachlor and metribuzin in soil. Pestic. Sci., 18, 95–111.
- 2. Corredor M.C., Rodriguez-Mellado J.M., Ruiz- Montoya M. 2006. EC(EE) process in the reduction of the herbicide clopyralid on mercury electrodes. Electrochim Acta, 51, 4302–4308.
- 3. Cuevas M.V., Cox L., Calderon M.J., Hermosin M.C., Fernandez J.E. 2007. Chloridazon and lenacil dissipation in a clayey soil of the Guadalquivir river marshes (southwest Spain). Agric. Ecos. Environ., 124(3–4), 245–251.
- 4. Dictor M., Baran N., Gautier A., Mouvet C. 2008. Acetochlor mineralization and fate of its two major metabolites in two soils under laboratory conditions. Chemosphere, 71, 663–670.
- 5. EFSA Scientific Report. 2005. Conclusion on the peer review of clopyralid, 50, 1–65.
- 6. Giller K.E., Witter E., McGrath S.P. 1998. Toxicity of heavy metals to microorganism and microbial processes in agricultural soils: A review. Soil Biol. Biochem., 30, 1389–2359.
- 7. Guo B.Y., Wei W.L., Lin J.M. 2009. The study of the interactions between heavy metals with sulfonylurea herbicides using ACE. J. Chromatographic Sci., 47, 116–120.
- 8. Hu J.Y., Zhen Z.H., Deng Z.B. 2011. Simultaneous determination of acetochlor and propisochlor residues in corn and soil by solid phase extraction and gas chromatography with electron capture detection. Bull. Environ. Contam, Toxicol., 86, 95–100.
- 9. Jaworska H., Dąbkowska-Naskręt D. 2012. Influence of Głogów Copper Works on the content of mobile forms of copper and zinc in arable soils. J. Elem., 17, 57–66.
- 10. Kabała C., Karczewska A., Kozak M. 2010. Przydatność roślin energetycznych do zagospodarowania gleb zdegradowanych. Zesz. Nauk. UP Wroc., Rol., XCVI, 576, 97–118 [In Polish].
- 11. Kucharski M., Sadowski J. 2011. Behaviour of metazachlor applied with additives in soil – laboratory and field studies. J. Food Agric. Environ., 9(3&4), 723–726.
- 12. Li H., Sheng G., Teppen B.J., Johnston C.T., Boyd S.A. 2003. Sorption and desorption of pesticides by clay minerals humic acid-clay complexes. Soil. Sci. Soc. Am. J., 67, 122–131.
- 13. Ma Q.L., Rahman A., James T.K., Holland P.T., McNaughton D.E., Rojas K.W., Ahuja L.R. 2004. Modeling the fate of acetochlor and terbuthylazine in the field using the Root Zone Water Quality Model. Soil Sci. Soc. Am. J., 68, 1491–1500.
- 14. Nwuche C.O., Ugoji E.O. 2008. Effects of heavy metal pollution on the soil microbial activity. Int. J. Environ. Sci. Tech., 5, 409–414.
- 15. Pieuchot M., Perrin-Ganier C., Portal J.M., Schiavon M. 1996. Study on the mineralization and degradation of isoproturon in three soils. Chemosphere, 33, 467–478.
- 16. Ravelli A., Pantani O., Calamai L., Fust P. 1997. Rates of chlorsulfuron degradation in three Brazilian oxisoils. Weed Res., 37, 51–59.
- 17. Rodriguez- Liebana J.A., Mingorance M.D., Pena A. 2013. Pesticide sorption on two contrasting mining soils by addition of organic wastes: Effect of organic matter composition and soil solution properties. Colloids and Surfaces A: Physicochem. Eng. Aspects, 435, 71–77.
- 18. Said W.A., Lewis D.L. 1991. Quantitative assessment of the effects of metals on microbial degradation of organic chemicals. Appl. Environ. Microbiol., 57, 1498–1503.
- 19. Sadeghi A.M., Isensee A.R., Shirmohammadi A. 2000. Influence of soil texture and tillage on herbicide transport. Chemosphere, 41, 1327–1332.
- 20. Smith A.E., Aubin A.J. 1989. Persistence studies with the herbicide clopyralid in prairie soils at different temperatures. Bull. Environ. Contam. Toxicol., 42, 670–675.
- 21. Suhadolc M., Schroll R., Gattinger A., Schloter M., Munch J.C., Lestan D. 2004. Effects of modified Pb-, Zn-, and Cd- availability on the microbial communities and on the degradation of isoproturon in a heavy metal contaminated soil. Soil Biol. Biochem., 36, 1943–1954.
- 22. Valery B., Eugene K. 1998. Soil surface geochemical anomaly around the copper-nickel metallurgical smelter. Water Air Soil Pollut., 103, 197–218.
- 23. Wang Y.P., Shi J.Y., Wang H., Lin Q., Chen X.C., Chen Y.X. 2007. The influence of soil heavy metals pollution on soil microbial biomass, enzyme activity, and community composition near a copper smelter. Ecotoxicol. Environ. Saf., 67, 75–81.
- 24. Wróbel S., Sadowski J. 2012. Interaction of copper and herbicide in contaminated soil under remediation. Fres. Environ. Bull., 21, 599–603.
- 25. Xu J., Yang M., Dai J., Cao H., Pan C., Qiu X., Xu M. 2008. Degradation of acetochlor by four microbial communities. Bioresource Technol., 99, 7797–7802.
- 26. Zhao P., Wang L., Chen L., Pan C. 2011. Residue dynamics of clopyralid and picloram in rape plant rapeseed and field soil. Bull. Environ. Contam. Toxicol., 86, 78–82.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-5736bdb0-9f38-4ea4-bfea-831918cddbb3