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Long-term Changes in the Stability of Agricultural Landscapes in the Areas of Irrigated Agriculture of the Ukraine Steppe Zone

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Spatio-temporal assessment of the sustainability of agricultural landscapes over a long period (1892–2020 – 130 years) was carried out on the basis of archival spatial data for the territory of the Dnieper district of the Tauride province and modern data from the State Agency for Water Resources of Ukraine. Taking into account the historical patterns of the development of agriculture on the territory of the Dnieper district and the results of spatial modeling in 1892, territories with low (4.1 thousand hectares – 0.3% of the total area) and medium (310.3 thousand hectares – 23.8%) level of sustainability of agricultural landscapes, which are located in the lower reaches of the Dnieper, were identified. However, the large-scale development of the territory for agricultural land and the development of irrigated agriculture have led to the activation of land degradation processes, soil fertility and the deterioration of the stability of agricultural landscapes over large areas. As a result of spatial modeling, the state for 2020 in the irrigation zone recorded significant areas of agricultural land and adjacent territories with low (179.1 thousand hectares – 13.7% of the total area) and medium (419.0 thousand hectares – 32.1%) stability level. A comparative analysis of the stability of agrolandscapes for two time periods (1892 and 2020) showed that large-scale agricultural land development and an imbalanced land-use culture lead to constant and almost irreversible processes of reducing the stability of agrolandscapes in the areas of irrigation reclamation.
Rocznik
Strony
188--198
Opis fizyczny
Bibliogr. 32 poz., rys., tab.
Twórcy
  • Kherson State Agrarian and Economic University, Stritens’ka Str. 23, 73006, Kherson, Ukraine
  • Kherson State Agrarian and Economic University, Stritens’ka Str. 23, 73006, Kherson, Ukraine
  • Mykolayiv National Agrarian University, George Gongadze Str. 9, 54020, Mykolayiv, Ukraine
  • National University of Life and Environmental Sciences of Ukraine, Heroiv Oborony Str. 15, 03041, Kiev, Ukraine
  • Kherson State Agrarian and Economic University, Stritens’ka Str. 23, 73006, Kherson, Ukraine
autor
  • Kherson National Technical University, Instytutsky Str. 11, 29016, Khmelnitsky, Ukraine
autor
  • Kherson State Agrarian and Economic University, Stritens’ka Str. 23, 73006, Kherson, Ukraine
Bibliografia
  • 1. Beznitska, N.V. 2017. Modeling of soil and climatic potential of agricultural lands of the Kherson region using GIS-technology. Herald of the National University of Water and Environmental Engineering, 4(76), 31–43. (in Ukrainian)
  • 2. Breus, D., Yevtushenko, O., Skok, S., Rutta, O. 2019. Retrospective studies of soil fertility change on the example of the Kherson region (Ukraine). International Multidisciplinary Scientific GeoConference Surveying Geology and Mining Ecology Management, SGEM, 19(5.1), 645–652.
  • 3. Breus, D., Yevtushenko, O., Skok, S., Rutta, O. 2020. Method of forecasting the agro-ecological state of soils on the example of the South of Ukraine. International Multidisciplinary Scientific GeoConference Surveying Geology and Mining Ecology Management, SGEM, 20(5.1), 523–528.
  • 4. Domaratskiy, E.O., Bazaliy, V.V., Domaratskiy, O.O., Dobrovolskiy, A.V., Kyrychenko, N.V., Kozlova, O.P. 2018. Influence of mineral nutrition and combined growth regulating chemical on nutrient status of sunflower. Indian Journal of Ecology, 45(1), 126–129.
  • 5. Domaratskiy, Y., Kozlova, O., Kaplina, A. 2020. Economic Efficiency of Applying Environmentally Friendly Fertilizers in Production Technologies in the South of Ukraine. Indian Journal of Ecology, 47(3), 624–629.
  • 6. Dudiak, N., Pichura, V., Potravka, L., Stratichuk, N. 2021. Environmental and economic effects of water and deflation destruction of steppe soil in Ukraine. Journal of Water and Land Development, 50, 10–26.
  • 7. Dudiak, N.V., Pichura, V.I., Potravka, L.A., Stratichuk, N.V. 2019. Geomodelling of Destruction of Soils of Ukrainian Steppe Due to Water Erosion. Journal of Ecological Engineering, 20(8), 192–198.
  • 8. Dudiak, N.V., Pichura, V.I., Potravka, L.A., Stroganov, A.A. 2020. Spatial modeling of the effects of deflation destruction of the steppe soils of Ukraine. Journal of Ecological Engineering, 21(2), 166–177.
  • 9. Dudiak, N.V., Potravka, L.A., Stroganov, A.A. 2019. Soil and Climatic Bonitation of Agricultural Lands of the Steppe Zone of Ukraine. Indian Journal of Ecology, 46(3), 534–540.
  • 10. Fagnano, M., Diodato, N., Alberico, I., Fiorentino, N. 2012. An overview of soil erosion modelling compatible with RUSLE approach. Rend. Fis. Acc. Lincei., 23, 69–80.
  • 11. Li, Y., Tang, C., Huang, Z., Hussain, Z., Are, K.S., Abegunrin, T.P., Qin, Z., Guo, H. 2020. Increase in farm size significantly accelerated stream channel erosion and associated nutrient losses from an intensive agricultural watershed. Agriculture, Ecosystems & Environment, 295, 106900.
  • 12. Lisetskii, F., Pichura, V. 2016. Steppe Ecosystem Functioning of East European Plain under Age-Long Climatic Change Influence. Indian Journal of Science and Technology, 9(18), 1–9.
  • 13. Lisetskii, F.N., Matsibora, A.V., Pichura, V.I. 2016. Geodatabase of Buried Soils for Reconstruction of Palaeoecologic Conditions in The Steppe Zone of East European Plain. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 7(5), 1637–1643.
  • 14. Lisetskii, F.N., Pavlyuk, Y.V., Kirilenko, Z.A., Pichura, V.I. 2014. Basin organization of nature management for solving hydroecological problems. Russian Meteorology and Hydrology, 39(8), 550–557.
  • 15. Luo, W., Zhao, W., Zhuang Y. 2018. Sand-burial and wind erosion promote oriented-growth and patchy distribution of a clonal shrub in dune ecosystems. CATENA, 167, 212–220.
  • 16. Martsinevskaya, L.V., Pichura, V.I., Tsybenko, V.V. 2018. Successive Steps to Organize Rational Use of Soils for Formation of Ecologically Stable Agro Landscapes. Research Journal of Pharmaceutical, Biological and Chemical Sciences, 9(3), 172–177.
  • 17. Mayovets, Y., Vdovenko, N., Shevchuk, H., Zos-Kior, М., Hnatenko, I. 2021. Simulation modeling of the financial risk of bankruptcy of agricultural enterprises in the context of COVID–19. Journal of Hygienic Engineering and Design, 36, 192–198.
  • 18. Medvedev, V.V., Plisko, I.V. 2006. Bonitation and qualitative assessment of arable land in Ukraine. Kharkov: 13 printing house, 386. (in Russian)
  • 19. Petrichenko, V.F., Zarishnyak, A.S., Balyuk, S.A., Polupan, M.I., Velichko, V.A., Solovey, V.B. 2013. Large-scale study of the soil cover of Ukraine is a strategic measure for its effective balanced use. Bulletin of Agrarian Science, 5, 5–13. (in Ukrainian)
  • 20. Pichura, V., Potravka, L., Dudiak, N., Stroganov, A., Dyudyaeva, O. 2021. Spatial differentiation of regulatory monetary valuation of agricultural land in conditions of widespread irrigation of steppe soils. Journal of water and land development, 48(I–III), 182–196.
  • 21. Pichura, V.I, Malchykova, D.S., Ukrainskij, P.A., Shakhman, I.A., Bystriantseva A.N. 2018. Anthropogenic Transformation of Hydrological Regime of The Dnieper River. Indian Journal of Ecology, 45(3), 445–453.
  • 22. Pichura, V.I., Breus, D.S. 2015. The Basin Approach in the Study of Spatial Distribution Anthropogenic Pressure With Irrigation Land Reclamation of the Dry Steppe Zone. Biogeosystem Technique, 3(1), 89–100.
  • 23. Pichura, V.I., Domaratsky, Y.A., Yaremko, Y.I., Volochnyuk, Y.G., Rybak V.V. 2017. Strategic Ecological Assessment of the State of the Transboundary Catchment Basin of the Dnieper River Under Extensive Agricultural Load. Indian Journal of Ecology, 44 (3), 442–450.
  • 24. Pichura, V.I., Lisetskii, F.N., Pavlyuk, Y.V. 2014. Secular variation of the stability of agricultural landscapes in the area of irrigation reclamation dry steppe zone (for example, south of the Kherson region). Belgorod State University Scientific Bulletin. Natural sciences, 17(188), 140–147. (in Russia)
  • 25. Pichura, V.I., Potravka, L.A., Dudiak, N.V., Skrypchuk, P.M., Stratichuk, N.V. 2019. Retrospective and Forecast of Heterochronal Climatic Fluctuations Within Territory of Dnieper Basin. Indian Journal of Ecology, 46(2), 402–407.
  • 26. Pichura, V., Potravka, L., Dudiak, N., Vdovenko, N. 2021. Space-Time Modeling of Climate Change and Bioclimatic Potential of Steppe Soil. Indian Journal of Ecology, 48(3), 671–680.
  • 27. Popov, M., Polyakova L. 1997. Pine forests in the sandy arenas of the Lower Dnieper: history, problems, prospects, 25. (in Russia)
  • 28. Rasmussen, C., Tabor, N.J. 2007. Applying a quantitative pedogenic energy model across a range of environmental gradients. Soil Science Society of America Journal, 71(6), 1719–1729.
  • 29. Terhoeven-Urselmans, T., Vagen, T., Spaargaren, O., Shepherd, K. 2010. Prediction of Soil Fertility Properties from a Globally Distributed Soil Mid-Infrared Spectral Library. Soil Science Society of America Journal, 5(74), 1792–1799.
  • 30. Ukrainskiy, P., Terekhin, E., Gusarov, A., Lisetskii, F., Zelenskaya. E. 2020. The influence of relief on the density of light-forest trees within the small-dry-valley network of uplands in the forest-steppe zone of Eastern Europe. Geosciences (Switzerland), 10(11), 1–18.
  • 31. Vdovenko, N., Tomilin, O., Kovalenko, L., Gechbaia, B., Konchakovski, E. 2022. Global trends and development prospects of the market of plant protection products. Agricultural and Resource Economics: International Scientific E-Journal, 8(2), 179–205. https://doi.org/10.51599/are.2022.08.02.10
  • 32. Volobuev, V.R. 1974. Introduction to the energetics of soil formation. Moscow: Nauka, 126. (in Russian)
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-22e327a6-cae1-4c3a-9a36-f95ce0e13bc7
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