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STUDY OF SOIL LOSS QUANTITY ON THE ARABLE TERRITORIES USING ESTIMATIONS OF SOIL POLLUTANTS MIGRATION AND GEOMORPHOMETRIC PARAMETERS OF THE MICRORELIEF
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Alifanov V.M., Gugalinskaya L.A., Ovchinnikov A.Yu., Paleokriogenez i raznoobrazie pochv centra Vostochno-Evropejskoj ravniny [Paleocryogenesis and soils variety of the center of East European Plain]. Moscow, GEOS, 2010. p. 160. (in Russian).
Costa-Cabral M.C., Burges S.J., Digital Elevation Model Networks (DEMON): A model of flow over hillslopes for computation of contributing and dispersal areas. International Multidisciplinary Scientific GeoConfenferences SGEM 2015 www.sgem.org 15th International Multidisciplinary Scientific GeoConferences SGEM2015 Water Resources Research, Vol. 30, Issue 6, 1994. pp. 1681 –1692. DOI: 10.1029/93WR03512
Evans I.S., General geomorphometry, derivations of altitude and descriptive statistics. In: R.J.Chorley (ed.). Spatial Analysis in Geomorphology. London : Methuen & Co. Ltd., Ch.2. 1972. pp. 7-90.
Golosov V.N., The ero sion-accumulative processes in river basins at cultivated plains. Moscow, GEOS, 2006. p. 296. (in Russian).
Larionov G.A., Soil erosion and deflation: basic laws and quantitative assessment . Moscow, MSU, 1993. p. 200. (in Russian).
Lastochkin A.N. , System-morphological base of Earth Sciences (geotopology, structural geography and the general theory of geosystems. SPSU, Saint- Petersburg, 2002. p. 762. (in Russian).
Markelov M.V., Modern erosion-accumulative processes in the upper segments of the hydrographic network of forest and forest-steppe zones. Abstract of PhD thesis, Moscow, 2004. p. 26. (in Russian).
Mitasova H., Brown W.M., Hohmann M., Warren S., Using Soil Erosion Modeling for Improved Conservation Planning: A GIS-based Tutorial. Available at: http://www4.ncsu.edu/~hmitaso/gmslab/reports/CerlErosionTutorial/denix/default .htm
Shary, P.A., Land surface in gravity points classification by a complete system of curvatures. Mathematical Geology, Volume 27, No. 3, 1995. pp. 373-390.
Stepanov I.N., Space and time in the science of soils, non Dokuchaev soil science. Moscow, Nauka, 2003. p. 400. (in Russian).
Timofeev D.A., Geomorphological and paleogeographic aspects of the problem of soil erosion. In: Reflections on fundamental problems of geomorphology. Selected works, Moscow, Media-Press, 2011. pp. 296-317. (in Russian).
Trofimetz L.N., Panidi E.A., Application of radio-cesium method to the research of the processes of washout and accumulation on arable slopes, which are complicated with ravine meso- and micro-reliefs: methodological approach and technique. Regional Evironmental Issues, Vol. 4, 2014. pp. 147-152. (in Russian).
Trofimetz L.N., Panidi E.A., Chaadaeva N.N., Indicative methods in studying of contemporary erosion network on the arable slopes, complicated with ravine relief. Scientific Notes of Orel State University Vol. 6(62). Orel State University, Orel, 2014. pp. 94-101. (in Russian).
Walling D.E., He Q., Improved models for estimating soil erosion rates from Caesium-137 measurements, Journal of Environmental Quality, Volume 28 , No. 2, 1999. pp. 611-622.
Webster, R., Quntitative and Numerical Methods in Soil Classification and Survey. Oxford: Oxford Univ. Press, 1977. 269p. International Multidisciplinary Scientific GeoConfenferences SGEM 2015 www.sgem.org
Alifanov V.M., Gugalinskaya L.A., Ovchinnikov A.Yu., Paleokriogenez i raznoobrazie pochv centra Vostochno-Evropejskoj ravniny [Paleocryogenesis and soils variety of the center of East European Plain]. Moscow, GEOS, 2010. p. 160. (in Russian).
Costa-Cabral M.C., Burges S.J., Digital Elevation Model Networks (DEMON): A model of flow over hillslopes for computation of contributing and dispersal areas. International Multidisciplinary Scientific GeoConfenferences SGEM 2015 www.sgem.org 15th International Multidisciplinary Scientific GeoConferences SGEM2015 Water Resources Research, Vol. 30, Issue 6, 1994. pp. 1681 –1692. DOI: 10.1029/93WR03512
Evans I.S., General geomorphometry, derivations of altitude and descriptive statistics. In: R.J.Chorley (ed.). Spatial Analysis in Geomorphology. London : Methuen & Co. Ltd., Ch.2. 1972. pp. 7-90.
Golosov V.N., The ero sion-accumulative processes in river basins at cultivated plains. Moscow, GEOS, 2006. p. 296. (in Russian).
Larionov G.A., Soil erosion and deflation: basic laws and quantitative assessment . Moscow, MSU, 1993. p. 200. (in Russian).
Lastochkin A.N. , System-morphological base of Earth Sciences (geotopology, structural geography and the general theory of geosystems. SPSU, Saint- Petersburg, 2002. p. 762. (in Russian).
Markelov M.V., Modern erosion-accumulative processes in the upper segments of the hydrographic network of forest and forest-steppe zones. Abstract of PhD thesis, Moscow, 2004. p. 26. (in Russian).
Mitasova H., Brown W.M., Hohmann M., Warren S., Using Soil Erosion Modeling for Improved Conservation Planning: A GIS-based Tutorial. Available at: http://www4.ncsu.edu/~hmitaso/gmslab/reports/CerlErosionTutorial/denix/default .htm
Shary, P.A., Land surface in gravity points classification by a complete system of curvatures. Mathematical Geology, Volume 27, No. 3, 1995. pp. 373-390.
Stepanov I.N., Space and time in the science of soils, non Dokuchaev soil science. Moscow, Nauka, 2003. p. 400. (in Russian).
Timofeev D.A., Geomorphological and paleogeographic aspects of the problem of soil erosion. In: Reflections on fundamental problems of geomorphology. Selected works, Moscow, Media-Press, 2011. pp. 296-317. (in Russian).
Trofimetz L.N., Panidi E.A., Application of radio-cesium method to the research of the processes of washout and accumulation on arable slopes, which are complicated with ravine meso- and micro-reliefs: methodological approach and technique. Regional Evironmental Issues, Vol. 4, 2014. pp. 147-152. (in Russian).
Trofimetz L.N., Panidi E.A., Chaadaeva N.N., Indicative methods in studying of contemporary erosion network on the arable slopes, complicated with ravine relief. Scientific Notes of Orel State University Vol. 6(62). Orel State University, Orel, 2014. pp. 94-101. (in Russian).
Walling D.E., He Q., Improved models for estimating soil erosion rates from Caesium-137 measurements, Journal of Environmental Quality, Volume 28 , No. 2, 1999. pp. 611-622.
Webster, R., Quntitative and Numerical Methods in Soil Classification and Survey. Oxford: Oxford Univ. Press, 1977. 269p. International Multidisciplinary Scientific GeoConfenferences SGEM 2015 www.sgem.org
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