Кліматична обумовленість ґрунтоутворення на території трансграничного басейну Дніпра

V. I. Pichura

doi:10.31548/bio2016.05.005

Authors

V. I. Pichura Kherson State Agricultural University , Херсонський державний аграрний університет

DOI:

https://doi.org/10.31548/bio2016.05.005

Abstract

The study employs the bioenergy approach and presents zone features of the impact of climate energy potential on the soil formation process on the territory of the transboundary Dnieper River basin using GIS technology.It presents the physical- geographical zoning, soil cover, granulometric composition, morphometric characteristics of the terrain, climatic characteristics (radiation balance, precipitation, energy consumption for soil formation, bioclimatic potential) of the Dnieper River’s catchment area. The research determines variation in the formation of the limit capacity of the humus horizon.

References

Semikolennykh A.A. (2010). Soil-like bodies of autochemolithotrophic ecosystems in the caves of the

https://doi.org/10.1134/S1064229310060025

kugitangtau ridge, eastern Turkmenistan. Eurasian Soil Science, 43 (6), 614-627.

Dokuchaev V.V. (1936). Russkiy chernozem [Russian black earth]. Report to Free Economic Society. M.-L.: Poligrafkniga, 550. (in Russian)

Lisetskii F.N., Pavlyuk Ya.V., Kirilenko Zh.A., Pichura V.I. (2014). Basin organization of nature management for solving hydroecological problems. Russian Meteorology and Hydrology, 39 (8), 550-557.

https://doi.org/10.3103/S106837391408007X

Ji Z., Li N., Xie W., et al. (2013). Comprehensive assessment of flood risk using the classification and

https://doi.org/10.1007/s00477-013-0716-z

regression tree method. Stoch Environ Res Risk Assess, 27, 1815-1828.

KuzmenkoY.V., Lisetskii F.N., Pichura V.I. (2012). Otsenka i prognozirovanie stoka malykh rek v usloviyakh antropogennykh vozdeystviy i izmeneniy klimata [Assessing and forecasting the runoff of small rivers under the conditions of anthropogenic impacts and climate change]. Modern problems of science and education, 6, 1-9. (in Russian)

Kim S., Kim B., Jun H., et al. (2014). Assessment of future water resources and water scarcity considering the factors of climate change and social-environmental change in Han River basin, Korea. Stoch Environ Res Risk Assess, 28, 1999-2014.

https://doi.org/10.1007/s00477-014-0924-1

Lisetskii F.N., Stolba V.F., PichuraV.I. (2013). Periodichnost' klimaticheskikh, gidrologicheskikh protsessov i ozernogo osadkonakopleniya na yuge Vostochno-Evropeyskoy ravniny [Frequency of climatic, hydrological processes and lake sedimentation in the south of the East European Plain]. Social and Scientific Journal "Problems of regional ecology", 4, 19-25. (in Russian)

Pichura V.I., Pilipenko Yu.V., Lisetskiy F.N., Dovbysh O.E. (2015). Forecasting of Hydrochemichal Regime of the Lower Dnieper Section using Neurotechnologies. Hydrobiological Journal, 51 (3), 100-110.

https://doi.org/10.1615/HydrobJ.v51.i3.80

Aziz K., Rahman A., Fang G., et al. (2014). Application of artificial neural networks in regional flood frequency analysis: a case study for Australia. Stoch Environ Res Risk Assess, 28, 541-554.

https://doi.org/10.1007/s00477-013-0771-5

Dawson C.W., Wilby R.L. (2001). Hydrological modeling using artificial neural networks. Hydrological modelling using artificial neural networks. Progress in Physical Geography, 25 (1), 80-108.

https://doi.org/10.1191/030913301674775671

Pichura V.I., Lisetskii F.N., Pavliuk Y.V. (2014). Vekovoe izmenenie ustoychivosti agrolandshaftov v zone orositel'nykh melioratsiy sukhostepnoy zony (na primere yuga Khersonskoy oblasti) [Secular changes in agricultural landscapes stability in the area of irrigation reclamation of the dry steppe zone (by the example of the south of the Kherson region)]. Scientific bulletin of Belgorod State University. Series: Natural sciences, 28, 17 (188), 140-147. (in Russian)

Volobuev V.R. (1974). Vvedenie v energetiku pochvoobrazovaniya [Introduction to Energetics of SoilFormation]. M.: Nauka, 126. (in Russian)

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.

https://doi.org/10.2136/sssaj2007.0051

Lisetskii F.N., Chepelev O.A. (2003). Klimaticheskaya obuslovlennost' pochvoobrazovaniya v Tsentral'nom Chernozem'e [Climatic conditionality of soil formation in the Central Black Earth Zone]. Bulletin of Voronezh State University. Series: Geography and geo-ecology, 2, 15-23. (in Russian)

Lisetskii F.N., Ergina E.I. (2010). Razvitie pochv Krymskogo poluostrova v pozdnem golotsene [Soil

development on the Crimean peninsula in the Late Holocene]. Soil science, 6, 643-657. (in Russian)

Lisetskii F.N., Pichura V.I. (2016). Assessment and forecast of soil formation under irrigation in the

https://doi.org/10.3103/S1068367416020075

steppe zone of Ukraine. Russian Agricultural Sciences, 2, 154-158. DOI: 10.3103/S 1068367416020075

Nesterenko V.P., Breus D.S. (2016). Geomodeling of the spatial distribution of climatic and economic energy consumption for soil formation in agricultural landscapes of the Crimean Peninsula.

Biogeosystem Technique, 8 (2), 160-174.

https://doi.org/10.13187/bgt.2016.8.160

Lisetskii F., Pichura V. (2016). Steppe ecosystem functioning of east European plain under age-long climatic

https://doi.org/10.17485/ijst/2016/v9i18/93780

change influence. Indian Journal of Science and Technology, 9 (18), 1-9.

Okolelova A.A., Rachimova N.A., Egorova G.S., Kasterina N.G., Zaikina V.N. (2015). Influence of Hydrogels on Productivity of Light-brown Soils. International Journal of Environmental Problems, 2 (2),

https://doi.org/10.13187/ijep.2015.2.117

Lisetskii F., Chepelev O. (2014). Quantitative substantiation of pedogenesis model key components.

Advances in Environmental Biology, 8 (4), 996-1000.

Pichura V.I. (2016). Struktura gidrogeomorfologichnoi' systemy dlja stvorennja geoosnovy ekologichnogo

karkasa basejnu richky Dnipro [Structure of the hydrogeomorphological system for creating the

geo-foundation for the ecological framework of the Dnieper river basin]. Bulletin of Dnepropetrovsk State Agricultural and Economic University, 2 (40), 19-25. (in Ukrainian).

Pichura V.I. Sil's'kogospodars'ke porushennja ekologichnoi' stijkosti basejnu richky Dnipro [Damage to

environmental sustainability of the Dnieper river basin caused by agriculture]. Scientific reports NUBiP Ukraine. 2016. № 5 (6). http://journals.nubip.edu.ua/index.php/Dopovidi/article/

view/7231/7010. (in Ukrainian)

Kalinichenko V.P. Endovitsky A.P., Minkina T.M., Skuratov N.S., Il'in V.B., Kim V.CH.-D. (2014). Upravlenie geokhimicheskimi protsessami v oroshaemykh pochvakh na tekhnologicheskoy platforme noosfery [Management of geochemical processes in irrigated soils on the technology platform of the noosphere]. Environmental Engineering, 3, 6-11. (in Russian)

Kalinichenko V.P. (2012). Biogeosistemotekhnika kak gnoseologicheskaya osnova upravleniya ekosistemami

[Biogeosystem technique as an epistemological framework for ecosystems managing]. Live and bioinert systems, 1. http://www.jbks.ru/archive/issue-1/article-3 (in Russian)

Climatic conditionality of soil formation on the territory of the transboundary Dnieper river basin

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