Ảnh hưởng đồng thời của cacbon hữu cơ hòa tan, chất hoạt động bề mặt và natri oxalat đến sự giải hấp thuốc trừ sâu
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DOI: https://doi.org/10.15625/0866-7144.2017-00411Keywords:
esponse surface methodology, modeling, fenobucarb, dissolve organic carbon, surfactantReferences
UNEP-chemicals. Stockholm Convention on Persistent Organic Pollutants, United Nation Environment Programme, http://www.pops.int/. (2004).
S. Tao, L. Q. Guo, X. J. Wang, W. X. Liu, T. Z. Ju, R. Dawson. Use of sequential ASE extraction to evaluate the bioavailability of DDT and its metabolites to wheat roots in soils with various organic carbon contents, Sci. Total Environ., 320(1), 1-9 (2004).
X. Wang, D. Wang, X. Qin, X. Xu. Residues of organochlorine pesticides in surface soils from college school yards in Beijing, China, Journal of Environmental Sciences, 20(9), 1090-6 (2008).
H. Nakata, Y. Hirakawa, M. Kawazoe, T. Nakabo, K. Arizono, S. I. Abe. Concentrations and compositions of organochlorine contaminants in sediments, soils, crustaceans, fishes and birds collected from Lake Tai, Hangzhou Bay and Shanghai city region, China, Environmental Pollution, 133(3), 415-29 (2005).
A. O. Barakat. Assessment of persistent toxic substances in the environment of Egypt, Environment International, 30(3), 309-22 (2004).
P. M. Hoai, Z. Sebesvari, T. B. Minh, P. H. Viet, F. G. Renaud. Pesticide pollution in agricultural areas of Northern Vietnam: Case study in Hoang Liet and Minh Dai communes, Environmental Pollution. 159(12), 3344-50 (2011).
A. O. Barakat, A. Mostafa, T. L. Wade, S. T. Sweet, N. B. Sayed. Assessment of persistent organochlorine pollutants in sediments from Lake Manzala, Egypt, Mar. Pollut. Bull., 64(8), 1713-20 (2012).
J. C. White, M. I. Mattina, W. Y. Lee, B. D. Eitzer, W. Iannucci-Berger. Role of organic acids in enhancing the desorption and uptake of weathered p,p′-DDE by Cucurbita pepo, Environmental Pollution, 124(1), 71-80 (2003).
L. Luo, S. Zhang, X. Q. Shan, Y. G. Zhu. Oxalate and root exudates enhance the desorption of p,p'-DDT from soils, Chemosphere, 63(8), 1273-9 (2006).
P. Wang, A. A. Keller. Particle-Size Dependent Sorption and Desorption of Pesticides within a Water-Soil-Nonionic Surfactant System, Environmental Science & Technology, 42(9), 3381-7 (2008).
K. Y. Cheng, J. W. C. Wong. Combined effect of nonionic surfactant Tween 80 and DOM on the behaviors of PAHs in soil–water system. Chemosphere, 62(11), 1907-16 (2006).
M. Gonzalez, K. S. Miglioranza, J. E. Aizpun, F. I. Isla, A. Pena. Assessing pesticide leaching and desorption in soils with different agricultural activities from Argentina (Pampa and Patagonia), Chemosphere, 81(3), 351-8 (2010).
P. Mukerjee, K. J. Mysels. Critical Micelle. Concentration of Aqueous Surfactant Systems, NSRDS-NBS 36 US Government Printing Office, Washington, DC (1971).
B. W. Strobel, H. C. B. Hansen, O. K. Borggaard, M. K. Andersen, K. Raulund-Rasmussen. Cadmium and copper release kinetics in relation to afforestation of cultivated soil, Geochimica et Cosmochimica Acta, 65(8), 1233-42 (2001).
B. B. Neto, I. S. Scarminio, R. E. Bruns. Chapter 6 Exploring the response surface. In: R.E. Bruns ISS, Neto BdB, editors, Data Handling in Science and Technology, 25, 245-312 (2005).
K. Kadokami, K. Tanada, K. Taneda, K. Nakagawa. Novel gas chromatography–mass spectrometry database for automatic identification and quantification of micropollutants, Journal of Chromatography A, 1089(1-2), 219-26 (2005).
Neto BB, Scarminio IS, Bruns RE. Chapter 5 Empirical Model-building. In: R. E. Bruns ISS, Neto BdB, editors, Data Handling in Science and Technology, 25, 199-244 (2005).
D. G. Jones. Piperonyl Butoxide. London: Academic Press, 317-23 (1999).
J. Luo, M. Ma, C. Liu, J. Zha, Z. Wang. Impacts of particulate organic carbon and dissolved organic carbon on removal of polycyclic aromatic hydrocarbons, organochlorine pesticides, and nonylphenols in a wetland, Journal of Soils and Sediments, 9(3), 180-7 (2009).
E. Maillard, S. Payraudeau, E. Faivre, C. Gregoire, S. Gangloff, G. Imfeld. Removal of pesticide mixtures in a stormwater wetland collecting runoff from a vineyard catchment, The Science of the total environment, 409(11), 2317-24 (2011).
L. Luo, S. Zhang, X. Q. Shan, Y. G. Zhu. Oxalate and root exudates enhance the desorption of p,p′-DDT from soils, Chemosphere, 63(8), 1273-9 (2006).
D. E. Kile, C. T. Chiou. Water solubility enhancements of DDT and trichlorobenzene by some surfactants below and above the critical micelle concentration, Environmental Science & Technology, 23(7), 832-8 (1989).
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