Abstract
The contemporary trend in the degradation of arable southern chernozems (Haplic Chernozems Pachic) in the steppe zone of south-eastern European Russia under the impact of water erosion has been evaluated based on a field study of changes in the deposition rate of eroded products on the bottoms of the currently stable negative landforms within a small catchment (1.92 km2 in area) with almost completely tilled slopes in the west of Orenburg oblast, in the basin of the Samara River (a left tributary of the Volga River). The dating of deposited sediments and the analysis of their temporal dynamics have been performed using the radioactive isotope 137Cs as a chronomarker. The results of a thorough analysis of catchment topography, grain size distribution data on soils and sediments, hydrometeorological observations, and satellite data have been used. It is found that the mean accumulation rate of chernozem erosion products on the bottom of a small catchment valley was 1.9–2.0 cm/year (16.5–28.4 kg/m2 annually) during the period of 1959–1986 (4.2–4.8 cm/year, or 30.4–83.5 kg/m2 annually in 1959–1963) compared to only 0.52–0.68 cm/year, or 6.6–11.9 kg/m2 annually, during the period of 1986–2016; i.e., the thickness of deposited sediments decreased at least by 3.0–3.6 times, and their mass decreased by 2.0–4.3 times (2.9 times on the average). It is shown that the main reason for the presumed significant decrease in the erosion rate of southern chernozems in the region during the last decades was the reduction in surface water runoff from slopes during the spring snowmelt period, as well as the probable change in the structure of crop rotation toward some increase in the share of perennial grasses, and erosion control measures.
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References
A. V. Apukhtin and M. V. Kumani, “Recent changes in the conditions of spring floods of rivers in Kursk region,” Elec. Sci. Jour. of the Kursk. St. Univ., No. 1, 300–311 (2012) [in Russian].
Atlas of Radioactive Pollution of European Russia, Belarus, and Ukraine, Ed. by Yu. A. Izrael’ (Roskartografiya, Moscow, 1998) [in Russian].
A. T. Barabanov, Agricultural Forest Melioration in Soil Protective Farming (All-Russian Scientific Research Institute of Agricultural Forest Melioration, Volgograd, 1993) [in Russian].
O. N. Bulygina, N. N. Korshunova, and V. N. Razuvaev, Extreme climate in Russia. http://meteo.ru/pogoda-i-klimat/196-extremclim. Reference date: August 7, 2017.
N. Werth, Histoire de l’Union Soviétique. De l’Empire Russe à la Communauté des États Indépendants (1900–1991) (Presses Universitaires de France, Paris, 1991; Progress-Akademiya, Moscow, 1992).
I. M. Gabbasova, R. R. Suleimanov, I. K. Khabirov, M. A. Komissarov, M. Fruehauf, P. Liebelt, T. T. Garipov, L. V. Sidorova, and F. Kh. Khaziev, “Temporal changes of eroded soils depending on their agricultural use in the southern Cis-Ural region,” Eurasian Soil Sci. 49 (10), 1204–1210 (2016). doi 10.1134/S1064229316100070
Geographical Atlas of Orenburg Oblast (DIK, Moscow, 1999) [in Russian].
V. N. Golosov, Erosion and Deposition Processes in River Basins of Cultivated Plains (GEOS, Moscow, 2006) [in Russian].
V. N. Golosov, V. R. Belyaev, M. V. Markelov, and E. N. Shamshurina, “Specifics of sediment redistribution within a small arable catchment during different periods of its cultivation (Gracheva Loshchina catchment, Kursk oblast),” Geomorfologiya, No. 1, 25–35 (2012). doi 10.15356/0435-4281-2012-1-25-35
V. N. Golosov, A. N. Gennadiev, K. R. Olson, M. V. Markelov, A. P. Zhidkin, Yu. G. Chendev, and R. G. Kovach, “Spatial and temporal features of soil erosion in the forest-steppe zone of the East European Plain,” Eurasian Soil Sci. 44 (7), 794–801 (2011).
V. N. Golosov, N. N. Ivanova, A. V. Gusarov, and A. G. Sharifullin, “Assessment of the trend of degradation of arable soils on the basis of data on the rate of stratozem development obtained with the use of 137Cs as a chronomarker,” Eurasian Soil Sci. 50 (10), 1195–1208 (2017). doi 10.1134/S1064229317100039
V. N. Golosov, I. V. Ostrova, A. N. Silant’ev, and I. G. Shkuratova, “Radioisotope technique of assessment of the present-day deposition rate within drainage basins,” Geomorfologiya, No. 1, 30–36 (1992) [in Russian].
A. V. Gusarov, “The main regularities of the ratio between riverbed and basin components of erosion and suspended sediment flux in the Northern Eurasia’s river basins,” Geomorfologiya, No. 4, 3–20 (2015) [in Russian]. doi 10.15356/0435-4281-2015-4-3-20
A. V. Gusarov, “Riverbed and basin components of erosion and suspended sediments runoff within river basins: a new method of assessment,” Geomorfologiya, No. 2, 23–39 (2013) [in Russian]. doi 10.15356/0435-4281-2013-2-23-39
A. P. Dedkov and V. I. Mozzherin, Erosion and Sediment Yield on the Earth (Kazan State Univ., Kazan, 1984) [in Russian].
The Unified State Register of Soil Resources of Russia. http://egrpr.esoil.ru. Reference date: August 10, 2017
The History of Orenburg Region, Ed. by L. I. Futoryanskii (Orenburgsk. Knizhn. Izd., Orenburg, 1996) [in Russian].
Climate of Russia, Ed. by N. V. Kobysheva (Gidrometeoizdat, St. Petersburg, 2001) [in Russian].
M. A. Komissarov and I. M. Gabbasova, “Snowmeltinduced soil erosion on gentle slopes in the southern Cis-Ural region,” Eurasian Soil Sci. 47 (6), 598–607 (2014). doi 10.1134/S1064229314060039
L. F. Litvin, V. N. Golosov, N. G. Dobrovol’skaya, N. N. Ivanova, Z. P. Kiryukhina, and S. F. Krasnov, “Stationary studies of snowmelt erosion in the Central Nonchernozemic Region,” Eroziya Pochv i Ruslovye Protsessy, No. 11, 57–76 (1997) [in Russian].
M. V. Markelov, V. N. Golosov, and V. R. Belyaev, “Changes in the sedimentation rates on the floodplains of small rivers in the Central Russian Plain,” Vestn. Mosk. Univ., Ser. 5: Geogr., No. 5, 70–76 (2012) [in Russian].
A. M. Rusanov and E. A. Milyakova, “Role of landscape asymmetry in development of soils and soil cover in the Cis-Ural region,” Vestn. Orenburg. Gos. Univ., No. 4, 108–113 (2005) [in Russian].
A. N. Silant’ev and I. G. Shkuratova, Identification of the Industrial Pollution of Soils and Atmospheric Fallout against the Background Global Fallout (Gidrometeoizdat, Leningrad, 1983) [in Russian].
Topographic Map, Scale 1: 25000, Sheet V-23-29-B-v Compiled According to Survey Data of 1972 (General Office of Geodesy and Cartography, Moscow, 1981) [in Russian].
N. L. Frolova, M. B. Kireeva, S. A. Agafonova, V. M. Evstigneev, N. A. Efremova, and E. S. Povalishnikova, “Lowland Rivers Runoff Within-year Distribution and Changes on the European Territory of Russia,” Water Sector of Russia: Prob., Tech., Man., 4, 4–20 (2015) [in Russian].
M. H. I. Dore, “Climate change and changes in global precipitation patterns: what do we know?” Environ. Int. 31 (8), 1167–1181 (2005).
V. N. Golosov, V. R. Belyaev, and M. V. Markelov, “Application of Chernobyl-derived 137Cs fallout for sediment redistribution studies: lessons from European Russia,” Hydrol. Process. 27 (6), 781–794 (2013). doi 10.1002/hyp.9470
V. Golosov, A. Gusarov, L. Litvin, O. Yermolaev, N. Chizhikova, G. Safina, and Z. Kiryukhina, “Evaluation of soil erosion rates in the southern half of the Russian Plain: methodology and initial results,” Proc. IAHS 375, 23–27 (2017).
P. Y. Groisman, R. W. Knight, and O. G. Zolina, “Recent trends in regional and global intense precipitation patterns,” in Climate Vulnerability: Understanding and Addressing Threats to Essential Resources (Academic, Oxford, 2013), V. 5, pp. 25–55.
D. I. Higgit, “The development and application of caesium-137 measurements in erosion investigation,” in Sediment and Water Quality in River Catchments (John Wiley&Sons Ltd, Chichester, 1995), pp. 287–305.
R. J. Loughran, “The use of the environmental isotope caesium-137 for soil erosion and sedimentation studies,” Trends in Hydrology 1, 149–167 (1994).
M. McNutt, “Climate change impacts,” Science 341 (6145), 435 (2013). doi 10.1126/science.1243256
R. L. Parfitt, W. T. Baisden, C. W. Ross, B. J. Rosser, L. A. Schipper, and B. Barry, “Influence of erosion and deposition on carbon and nitrogen accumulation in resampled steepland soils under pasture in New Zealand,” Geoderma 192 (1), 154–159 (2013). doi 10.1016/j.geoderma.2012.08.006
P. Porto, D. E. Walling, and G. Callegari, “Using 137Cs measurements to establish catchment sediment budgets and explore scale effects,” Hydrol. Process. 25 (6), 886–900 (2011). doi 10.1002/hyp.9471
A. M. Rusanov and L. V. Anilova, “The humus formation and humus in forest-steppe and steppe chernozems of the Southern Cis-Ural region,” Eurasian Soil Sci. 42 (10), 1101–1108 (2009). doi 10.1134/S1064229309100044
D. E. Walling, V. N. Golosov, A. V. Panin, and Q. He, “Use of radiocaesium to investigate erosion and sedimentation in areas with high levels of Chernobyl fallout,” in Tracers in Geomorphology (John Wiley&Sons Ltd, Chichester, 2000), pp. 183–200.
F. Zapata, Handbook for the Assessment of Soil Erosion and Sedimentation Using Environment Radionuclides (Kluwer Academic Publishers, Dordrecht, 2002).
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Original Russian Text © A.V. Gusarov, V.N. Golosov, A.G. Sharifullin, A.M. Gafurov, 2018, published in Pochvovedenie, 2018, No. 5, pp. 601–616.
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Gusarov, A.V., Golosov, V.N., Sharifullin, A.G. et al. Contemporary Trend in Erosion of Arable Southern Chernozems (Haplic Chernozems Pachic) in the West of Orenburg Oblast (Russia). Eurasian Soil Sc. 51, 561–575 (2018). https://doi.org/10.1134/S1064229318050046
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DOI: https://doi.org/10.1134/S1064229318050046