Effect of two selected herbicides (Nicosulfuron + Atrazine and Dimethylammonium Acetate) on microbial activities and physicochemical properties of soil samples

Yıl 2021, Cilt: 10 Sayı: 2, 12 - 22, 31.08.2021

Adewole Sebiomo Folake Banjo

Öz

This study investigated the effect of Dimethylammonium Acetate and Nicosulfuron + Atrazine on soil microbial activities and physicochemical properties, applied at X1, X2, and X3 rates. Dehydrogenase activity, Microbial biomass carbon, available phosphorus, total nitrogen, organic matter, mineral content, electrical conductivity, exchangeable acidity and pH were determined in the soil samples. There were significant reductions (P≤0.05) in the dehydrogenase activities of soil samples treated with the two herbicides compared to the control. Treatment with the herbicides also resulted in significant increases (P≤0.05) in the total nitrogen and available phosphorus content of soil samples compared to the control soil samples. Dimethylammonium Acetate treated soils had the lowest dehydrogenase activity (26.33±0.9 µgg-1h-1) of the two herbicides. Soil treatment with Dimethylammonium Acetate resulted in significant increases (P≤0.05) in calcium, magnesium, sodium, potassium, manganese, copper, and zinc content of soil samples. The manganese content of the soil samples was highest (7.29 ± 0.20 mg/kg) in soils treated with Dimethylammonium Acetate. Dimethylammonium Acetate treated soils also had the highest exchangeable acidity and electrical conductivity values of 0.85 ± 0.08 Cmol kg -1 and 1.75 ± 0.14 Cmol kg -1, respectively, at X3. Conclusively Dimethylammonium Acetate caused a noticeable increase in dehydrogenase activity and microbial biomass carbon content, while application of Nicolsufuron + Atrazine resulted in an increase in dehydrogenase activity and a decrease in microbial biomass carbon.

Anahtar Kelimeler

Microbial biomass carbon, Available phosphorus, Total nitrogen, Organic matter, Mineral content

Kaynakça

• M. E. Pampulha, A. Oliveira, Impact of an herbicide combination of Bromoxynil and Prosulfuron on soil microorganisms, Current Microbiology, 53, (2006) 238-243.
• A. Sebiomo, V. W. Ogundero, S. A. Bankole, Effect of four herbicides on microbial population, soil organic matter and dehydrogenase activity, African Journal of Biotechnology, 10(5), (2011) 770-778.
• S. M. Holloway, M. Bentham, K. Kirk, Underground storage of carbon dioxide: An intergrated assessment, Ashgate Publishing Limited, Eds., Simon Shackley, Clair Gough, (2006).
• W. H. Zhong, Z. Cai, Long-term effects of inorganic fertilizers on microbial biomass and community functional diversity in a paddy soil derived from quaternary red clay, Applied Soil Ecology, 36(2), (2007) 84-91.
• R. Canet, J. G. Birnstingl, D. G. Malcolm, J. M. Real-Lopez, A. J. Beck, Biodegradation of polycyclic aromatic hydrocarbons (PAHS) by native microflora and combinations of white-rot fungi in a coal tar contaminated soil, Bioresource Technology, 76, (2001) 113-17.
• S. Kumar, S. Chaudhuri, S. K. Maiti. Soil Dehydrogenase enzyme activity in natural and mine soil - A review, Middle East Journal of Scientific Research; 13(7), (2013) 898-906.
• E. D. Vance, P. C. Brookes, D. S. Jenkinson, An extraction method for measuring soil microbial biomass C, Soil Biology and Biochemistry, 17(6), (1987) 837-842.
• J. D. Rhodes. Salinity, Electrical conductivity, and total dissolved solids, Methods of soil analysis. Part 3. Chemical methods, D. L. Sparks (Ed), Soil Science Society of America, Madison, Wisconsin, USA, pp. 417-435, 1996.
• Food and Agriculture Organisation. Soil map of the world Volume 1, Legend, FAO Rome Italy, p. 59, 2006.
• V. J. G. Houba, J.J. van der Lee, L. Novosamsky, L. Walinga, Soil and plant analysis part 5: soil analysis procedures, Wageningen agricultural university, The Netherlands, 1988.
• L. C. Blakemore, P. L. Searle, B. K. Daly, Methods for chemical analysis of soils, N. Z. Soil Bureau Sci. Rep. 80. Soil Bureau, Lower Hutt, 1987.
• L. Gianfreda, F. Sannino, Pesticide influence on soil enzymatic activities, Journal of Chemosphere, 45, (2001) 417-425.
• L. Gianfreda, M. Rao, Interactions between xenobiotics and microbial and enzymatic soil activity, Environmental Science and Technology, 38, (2008) 269-310.
• M. Baćmaga, E. Boros, J. Kucharski, J. Wyszkowska, Enzymatic activity in soil contaminated with the Aurora 40 WG herbicide, Environment Protection Engineering, 38(1), (2012) 91–102.
• J. L. Moreno, A. Aliaga, S. Navarro, T. Hernandez, C. Garcia, Effect of Atrazine on microbial activity in semiarid soil, Applied Soil Ecology, 35, (2007) 120-127.
• M. Panettieri, L. Lazaro, R. Lopez-Garrido, J. M. Murillo, E. Madejon, Glyphosate effect on soil biochemical properties under conservation tillage, Journal of Soil Tillage Research, 133, (2013) 16-24.
• M. C. Zabaloy, J. L. Garland, M. A. Gómez, An integrated approach to evaluate the impacts of the herbicides glyphosate, 2, 4 D and metsulfuron-methyl on soil microbial communities in the Pampas region, Argentina. Applied Soil Ecology, 40, (2008) 1-12.
• E. Gomez, L. Ferreras, L. Lovotti, E. Fernandez, Impact of glyphosate application on microbial biomass and metabolic activity in a Vertic Argiudoll from Argentina. European Journal of Soil Biology, 45, (2009) 163–167.
• A. S. F. Araújo, R. T. R. Monteiro, R. B. Abarkeli, Effect of glyphosate on the microbial activity of two Brazilian soils. Chemosphere, 52(5), (2003) 799-804.
• A. C. Das, A. Debnath, Effect of systemic herbicides on N2-fixing and phosphate solubilizing microorganisms in relation to availability of nitrogen and phosphorus in paddy soils of West Bengal. Chemosphere, 65, (2006) 1082-1086.
• A. C. Das, S. J. Das, S. Dey, Effect of herbicides on microbial biomass in relation to availability of plant nutrients in soil, Journal of Crop and Weed, 8(1), (2012) 129-132.
• W. Tahar, O. Bordjiba, L. Mezedjri. Impact of two Pesticides on Soil Physicochemical Characteristics and the Biological Activity, Journal of Chemical and Pharmaceutical Sciences, 10(2), (2017) 803-808.