KnE Life Sciences
ISSN: 2413-0877
The latest conference proceedings on life sciences, medicine and pharmacology.
Trace Element Content in the Soils of the Forest-Steppe of Western Siberia
Published date: Apr 05 2021
Journal Title: KnE Life Sciences
Issue title: DonAgro: International Research Conference on Challenges and Advances in Farming, Food Manufacturing, Agricultural Research and Education
Pages: 153–160
Authors:
Abstract:
This research is based on local monitoring in 1994-2018 on reference plots of agricultural lands and materials of a large-scale agrochemical survey. The research examined the soils of the forest-steppe zone of the Omsk Region: ordinary chernozem low-power low-humus heavy loamy soil; meadow-chernozem medium-thick medium-humus heavy loamy soil; and solonetz meadow chernozemic deep low humus clay soil. It was found that almost the entire surveyed area of arable land in the forest-steppe zone of the Omsk Irtysh Land (98.1 %) had low mobile zinc availability with an average level of 0.85 mg/kg. 41.1% of arable land had low mobile manganese availability, 41.3% had medium and 17.6% had high availability; the weighted average was 13.0 mg/kg. Most of the arable land was characterized by a low degree of mobile copper content security (81.2%), while 18.3% of the land had soil with an average content, and only 0.5% of the land had high mobile copper content. The average concentration was 20.0 mg/kg. The soil levels of mobile molybdenum availability wereas follows: 71.6% of land had medium availability, 26.5% had high, and only 1.9% had low; the weighted average concentration was 0.20 mg/kg. All soils had a high degree of mobile forms of boron, while the weighted average was 2.69 mg/kg of soil. 67.8% of the area had low mobile cobalt availability, 31.6% had average availability, and 0.5 % had high availability, with an average concentration of 0.16 mg/kg in the zone. The reference plots did not differ in terms of their content of mobile zinc, copper, and cobalt, ordinary chernozems, meadow chernozem soils, and deep solonetz. Movable connections of molybdenum, manganese, and boron in ordinary chernozem were lower than in meadow chernozem soil, and the maximum ones were observed in solonetz meadow chernozemic deep.
Keywords: trace elements, content, soil, survey, dynamics, Omsk region
References:
[1] Azarenko, Y.A. (2019). Assessing the Fund of Strongly Bound and Mobile Forms of Zinc in the Soils of Agrocenoses in the Forest-Steppe and Steppe Zones of the Omsk Irtysh Land.Annals of Biology, vol. 35, issue 1, pp. 67-72.
[2] Azarenko, Y.A., Ermoxin, Y.I. and Aksenova, Y.V.(2019). Zinc in Soils of Agrocenoses of the Omsk Irtysh Land and the Efficiency of Zinc Fertilizers. Agriculture,vol. 2, pp. 13-17.
[3] Parkhomenko, N., Garagul, A. and Shayakhmetov, M. (2019).The Use of Remote Sensing Methods to Study the Ecological State of Agricultural Soils.Proceedings of the International Scientific Conference the Fifth Technological Order: Prospects for the Development and Modernization of the Russian AgroIndustrial Sector (TFTS 2019), vol. 1,pp. 269-273.
[4] Azarenko, Y.A. (2019).Assessing the Fund of Strongly Bound and Mobile Forms of Zinc in the Soils of Agrocenoses in the Forest-Steppe and Steppe Zones of the Omsk Irtysh Land.Annals of Biology, vol.35, issue 1, pp. 67-72.
[5] Bobrenko, I.A., et al. (2019). Efficiency of Foliar Feeding with Zinc and Copper Chelates of Spring Soft Wheat in the Conditions of the Southern Forest-Steppe of the Omsk Irtysh Region.Advances in Social Science, Education and Humanities Research. The Fifth Technological Order: Prospects for the Development and Modernization of the Russian Agro-Industrial Sector, vol. 393, pp. 232-235.
[6] Bobrenko, I.A., et al.(2017). Improving Competitiveness of the Wheat Production within the Siberian Region (in Terms of the Omsk region).Journal of Advanced Research in Law and Economics, vol. 2, issue 24, pp. 426-436.
[7] Boldysheva, E. P.(2013). Optimisation of Zinc Fertiliser Application in Winter Rye Cultivation in Western Siberia.Collection of scientific papers by the Stavropol Livestock and Feed Production Research Institute, vol. 3, issue 6, pp. 36-39.
[8] Boldysheva, E. P.(2018). Diagnostics and Optimization of Micronutrient Feeding of Winter Rye on Meadow-Chernozem Soil of Western Siberia: Candidate of Science (PhD) Dissertation (Agricultural Sciences). Omsk, 2018. (in russ.). (Dissertation, 2018).
[9] Ermokhin, Y. I., Parshutkin, N. Y. and Garagul, A. S. (2019). The Mathematical Modeling of Mobile Zinc and Cobalt Level in Soil.Earth and Environmental Science, vol. 315, p. 022080.
[10] Krasnitszkii, V.M., Shmidt, A.G. and Cyrk, A.A. (2014). Zinc Content in Soils of Omsk Region.Fertility, vol. 4, issue 79, pp. 36-37.
[11] Krasnitszkii, V.M., et al. (2016). Agroecological Monitoring of Soils on the Right Bank of Irtysh ForestSteppe Zone of Omsk Region.Fertility, vol. 3, pp. 33-36.
[12] Krasnitszkii, V.M. and Azarenko, Y.A. (2017). Content of Microelements in the Soil-Plant System in Agrocenoses of Omsk Irtysh Land.Fertility, vol. 5, issue 98, pp. 28-31.
[13] Adriano, D.C., Paulsеn, G.M. and Murphy, L.S. (1971). Phosphorus-iron and Phosphorus-Zinc Relationships in Corn (Zea MaysL.) Seedlings as Mineral Nutrition Agronomy. J., vol. 63, pp. 36-39.
[14] Singh, M. and Singh, R.S. (1979). Response of Wheat No Zinc Fertilization at Different of Levels of Phosphorus in a Loamy Sand Soil. Journal Indian. Society Soil Science, vol.27, vol.3, pp. 209-216.
[15] Verma, T.S. and Trapthi, B.R. (1986). Interaction effects of P-Zn and P-Cu on Dry Matter Yield MicroNutrient Availability to Rice in Water-Logged Alfisols. Acta. Agronomica Hungarica, vol. 35, issue 1-2, pp. 83-90.