Sustainable Remediation of Atrazine in Agricultural Fields by Reusing Contaminated Water for Irrigation
Year 2022,
Volume: 26 Issue: 1, 136 - 148, 28.02.2022
Zohre Kurt
Abstract
High yields of agricultural produce is reached traditionally by the application of fertilizers and/or pesticides. When agricultural soil is saturated with pesticides, any pesticide addition to the soil leaches and thus reaches the underlying groundwater. Preventing further contamination and remediation of this type of contamination remains to be a challenge. Although monitored natural attenuation has been shown as an ultimate solution for decontamination, additional applications have been introduced to rapidly achieve this goal. One solution that also contains economic benefits to the farmers is to pump and reuse. The study described here evaluates the possibility to use pump and reuse technique for two common pesticides with different chemical properties, namely atrazine and cypermethrin. In this study, six field samples have been evaluated for their pesticide biodegradation capacity. By placing them in sterilized controls and inoculated active columns, field conditions are replicated to study the leaching and biodegradation at the topsoil of agricultural fields. The biodegradation capacities of inoculated active columns ranged between 34 and75 mg/kg/day for atrazine. The results indicated that using the contaminated water for irrigation could eliminate the pesticide contamination from the soil and groundwater. Overall, this method provides a sustainable solution for pesticide use and remediation by minimizing the pesticide use in agricultural fields without affecting the yield of the planted crops.
Supporting Institution
Middle East Technical University
Project Number
YOP-311-2018-2828
Thanks
This study was supported by ODTU BAP Project number YOP-311-2018-2828, TUBITAK Project number 118C013, Turkey and by El Sistema Nacional de Investigación (SNI) (National Scientist Membership) SNI No. 10-2018, SENACYT, Panama City, Panama.
References
- [1] A. Abdullah, S. Brobst, I. Pervaiz, M. Umer, and A. Nisar, "Learning dynamics of pesticide abuse through data mining," in Proceedings of the second workshop on Australasian information security, Data Mining and Web Intelligence, and Software Internationalisation-Volume 32, 2004: Australian Computer Society, Inc., pp. 151-156.
- [2] D. I. Gustafson, "Groundwater ubiquity score: a simple method for assessing pesticide leachability," Environmental Toxicology and Chemistry: An International Journal, vol. 8, no. 4, pp. 339-357, 1989.
- [3] Y. Zhao and Y. Pei, "Risk evaluation of groundwater pollution by pesticides in China: a short review," Procedia Environmental Sciences, vol. 13, pp. 1739-1747, 2012.
- [4] D. L. Hoag and A. G. Hornsby, "Coupling groundwater contamination with economic returns when applying farm pesticides," Journal of environmental quality, vol. 21, no. 4, pp. 579-586, 1992.
- [5] C. Niti, S. Sunita, K. Kamlesh, and K. Rakesh, "Bioremediation: An emerging technology for remediation of pesticides," Research Journal of Chemistry and Environment, vol. 17, p. 4, 2013.
- [6] C. Kao, C. Chai, J. Liu, T. Yeh, K. Chen, and S. Chen, "Evaluation of natural and enhanced PCP biodegradation at a former pesticide manufacturing plant," Water research, vol. 38, no. 3, pp. 663-672, 2004.
- [7] D. K. Singh, "Biodegradation and bioremediation of pesticide in soil: concept, method and recent developments," Indian journal of microbiology, vol. 48, no. 1, pp. 35-40, 2008.
- [8] W. A. Jury, D. D. Focht, and W. J. Farmer, "Evaluation of Pesticide Groundwater Pollution Potential from Standard Indices of Soil-Chemical Adsorption and Biodegradation 1," Journal of environmental quality, vol. 16, no. 4, pp. 422-428, 1987.
- [9] X. Zhang, X. Zhu, R. Chen, S. Deng, R. Yu, and T. Long, "Assessment of Biodegradation in Natural Attenuation Process of Chlorinated Hydrocarbons Contaminated Site: An Anaerobic Microcosm Study," Soil and Sediment Contamination: An International Journal, vol. 29, no. 2, pp. 165-179, 2020.
- [10] G. Hatipoglu and Z. Kurt, "Modeling irrigation with nitrate contaminated groundwater," Pamukkale Univ Muh Bilim Derg, vol. 1000, no. 1000, pp. 0-0, 2019, doi: 10.5505/pajes.2019.38963.
- [11] U. Dorigo, X. Bourrain, A. Berard, and C. Leboulanger, "Seasonal changes in the sensitivity of river microalgae to atrazine and isoproturon along a contamination gradient," Science of the Total Environment, vol. 318, no. 1-3, pp. 101-114, 2004.
- [12] D. Belluck, S. Benjamin, and T. Dawson, "Groundwater contamination by atrazine and its metabolites: risk assessment, policy, and legal implications," ACS Publications, 1991.
- [13] A. Gawel, B. Seiwert, S. Sühnholz, M. Schmitt-Jansen, and K. Mackenzie, "In-situ treatment of herbicide-contaminated groundwater-Feasibility study for the cases atrazine and bromacil using two novel nanoremediation-type materials," Journal of Hazardous Materials, p. 122470, 2020.
- [14] K. Jayachandran, T. Steinheimer, L. Somasundaram, T. B. Moorman, R. S. Kanwar, and J. R. Coats, "Occurrence of atrazine and degradates as contaminants of subsurface drainage and shallow groundwater," Journal of environmental quality, vol. 23, no. 2, pp. 311-319, 1994.
- [15] H. Pionke and D. Glotfelty, "Contamination of groundwater by atrazine and selected metabolites," Chemosphere, vol. 21, no. 6, pp. 813-822, 1990.
- [16] R. Wauchope, "The pesticide content of surface water draining from agricultural fields—a review 1," Journal of environmental quality, vol. 7, no. 4, pp. 459-472, 1978.
- [17] S. Beegum, J. Vanderborght, J. Šimůnek, M. Herbst, K. Sudheer, and I. M. Nambi, "Investigating Atrazine Concentrations in the Zwischenscholle Aquifer Using MODFLOW with the HYDRUS-1D Package and MT3DMS," Water, vol. 12, no. 4, p. 1019, 2020.
- [18] Cornell University College of Agricultural and Life Sciences. "Atrazine Application Rates." Cornell University College of Agricultural and Life Sciences. https://fieldcrops.cals.cornell.edu/corn/weed-control-corn/atrazine-application-rates/ (accessed 13/11/19, 2019).
- [19] J. Bethsass and A. Colangelo, "European Union bans atrazine, while the United States negotiates continued use," International journal of occupational and environmental health, vol. 12, no. 3, pp. 260-267, 2006.
- [20] P. K. Kalita, R. S. Kanwar, J. L. Baker, and S. W. Melvin, "Groundwater residues of atrazine and alachlor under water-table management practices," Transactions of the ASAE, vol. 40, no. 3, pp. 605-614, 1997.
- [21] S. K. Abd-Elmabod et al., "Modeling agricultural suitability along soil transects under current conditions and improved scenario of soil factors," in Soil mapping and process modeling for sustainable land use management: Elsevier, 2017, pp. 193-219.
- [22] Solar dripper. "Drip irrigation efficiency and water saving." https://solar-dripper.com/en/drip-irrigation-efficiency/ (accessed 15/11/19, 2019).
- [23] J. Šimůnek, M. T. Van Genuchten, and M. Šejna, "Recent developments and applications of the HYDRUS computer software packages," Vadose Zone Journal, vol. 15, no. 7, 2016.
- [24] M. G. Bos, "Water requirements for irrigation and the environment," 2018.
- [25] S. S. Staff, "Soil survey manual," 1993.
- [26] R. D. Horrocks and J. F. Valentine, Harvested forages. Academic Press, 1999.
- [27] L. Yue, C. Ge, D. Feng, H. Yu, H. Deng, and B. Fu, "Adsorption–desorption behavior of atrazine on agricultural soils in China," Journal of Environmental Sciences, vol. 57, pp. 180-189, 2017.
- [28] S. A. Clay and W. C. Koskinen, "Characterization of alachlor and atrazine desorption from soils," Weed Science, pp. 74-80, 1990.
- [29] J. C. Spain, J. B. Hughes, and H.-J. Knackmuss, Biodegradation of nitroaromatic compounds and explosives. CRC Press, 2000.
- [30] S. Nasseri, M. Dehghani, S. Amin, K. Naddafi, and Z. Zamanian, "Fate of atrazine in the agricultural soil of corn fields in Fars province of Iran," Journal of Environmental Health Science & Engineering, vol. 6, no. 4, pp. 223-232, 2009.
- [31] A. Hildebrandt, S. Lacorte, and D. Barceló, "Assessment of priority pesticides, degradation products, and pesticide adjuvants in groundwaters and top soils from agricultural areas of the Ebro river basin," Analytical and bioanalytical chemistry, vol. 387, no. 4, pp. 1459-1468, 2007.
- [32] S. Rousseaux, A. Hartmann, and G. Soulas, "Isolation and characterisation of new Gram-negative and Gram-positive atrazine degrading bacteria from different French soils," FEMS Microbiology Ecology, vol. 36, no. 2-3, pp. 211-222, 2001.
- [33] N. Udiković-Kolić, C. Scott, and F. Martin-Laurent, "Evolution of atrazine-degrading capabilities in the environment," Applied microbiology and biotechnology, vol. 96, no. 5, pp. 1175-1189, 2012.
- [34] L. E. Erickson, K. H. Lee, and D. D. Sumner, "Degradation of atrazine and related s‐triazines," Critical Reviews in Environmental Science and Technology, vol. 19, no. 1, pp. 1-14, 1989.
- [35] M. Radosevich, S. J. Traina, Y.-L. Hao, and O. H. Tuovinen, "Degradation and mineralization of atrazine by a soil bacterial isolate," Applied and Environmental Microbiology, vol. 61, no. 1, pp. 297-302, 1995.
- [36] X. Fan and F. Song, "Bioremediation of atrazine: recent advances and promises," Journal of soils and sediments, vol. 14, no. 10, pp. 1727-1737, 2014.
- [37] S. Sagarkar et al., "Monitoring bioremediation of atrazine in soil microcosms using molecular tools," Environmental pollution, vol. 172, pp. 108-115, 2013.
- [38] L. Pussemier, S. Goux, V. Vanderheyden, P. Debongnie, I. Tresinie, and G. Foucart, "Rapid dissipation of atrazine in soils taken from various maize fields," Weed Research, vol. 37, no. 3, pp. 171-179, 1997.
- [39] M. Dehghani, S. Nasseri, and H. Hashemi, "Study of the bioremediation of atrazine under variable carbon and nitrogen sources by mixed bacterial consortium isolated from corn field soil in Fars Province of Iran," Journal of environmental and public health, vol. 2013, 2013.
- [40] H. Fang, J. Lian, H. Wang, L. Cai, and Y. Yu, "Exploring bacterial community structure and function associated with atrazine biodegradation in repeatedly treated soils," Journal of hazardous materials, vol. 286, pp. 457-465, 2015.
- [41] I. Mirgain, G. Green, and H. Monteil, "Degradation of atrazine in laboratory microcosms: isolation and identification of the biodegrading bacteria," Environmental Toxicology and Chemistry: An International Journal, vol. 12, no. 9, pp. 1627-1634, 1993.
- [42] M. Kah, S. Beulke, and C. D. Brown, "Factors influencing degradation of pesticides in soil," Journal of agricultural and food chemistry, vol. 55, no. 11, pp. 4487-4492, 2007.
- [43] H. Patel, "Fixed-bed column adsorption study: a comprehensive review," Applied Water Science, vol. 9, no. 3, pp. 1-17, 2019.
- [44] D. Lima et al., "Evaluating a bioremediation tool for atrazine contaminated soils in open soil microcosms: the effectiveness of bioaugmentation and biostimulation approaches," Chemosphere, vol. 74, no. 2, pp. 187-192, 2009.
- [45] M. S. Rodríguez-Cruz, J. E. Jones, and G. D. Bending, "Field-scale study of the variability in pesticide biodegradation with soil depth and its relationship with soil characteristics," Soil Biology and Biochemistry, vol. 38, no. 9, pp. 2910-2918, 2006.
- [46] C. A. Damalas and I. G. Eleftherohorinos, "Pesticide exposure, safety issues, and risk assessment indicators," International journal of environmental research and public health, vol. 8, no. 5, pp. 1402-1419, 2011.
- [47] F. R. Lamm and T. P. Trooien, "Subsurface drip irrigation for corn production: a review of 10 years of research in Kansas," Irrigation science, vol. 22, no. 3-4, pp. 195-200, 2003.
- [48] F. Ackerman, "The economics of atrazine," International Journal of Occupational and Environmental Health, vol. 13, no. 4, pp. 437-445, 2007.
- [49] J. Fernandez-Cornejo, R. F. Nehring, C. Osteen, S. Wechsler, A. Martin, and A. Vialou, "Pesticide use in US agriculture: 21 selected crops, 1960-2008," USDA-ERS Economic Information Bulletin, no. 124, 2014.
- [50] Z. Kurt, E. E. Mack, and J. C. Spain, "Biodegradation of cis-dichloroethene and vinyl chloride in the capillary fringe," Environmental science & technology, vol. 48, no. 22, pp. 13350-13357, 2014.
- [51] Z. Kurt, E. E. Mack, and J. C. Spain, "Natural attenuation of nonvolatile contaminants in the capillary fringe," Environmental science & technology, vol. 50, no. 18, pp. 10172-10178, 2016.
- [52] Z. Kurt and J. C. Spain, "Biodegradation of chlorobenzene, 1, 2-dichlorobenzene, and 1, 4-dichlorobenzene in the vadose zone," Environmental science & technology, vol. 47, no. 13, pp. 6846-6854, 2013.
- [53] J. Luo, Z. Kurt, D. Hou, and J. C. Spain, "Modeling aerobic biodegradation in the capillary fringe," Environmental science & technology, vol. 49, no. 3, pp. 1501-1510, 2015.