Authors: Tatiana V. Raudina, Sergey P. Kulizhskiy

Abstract:

A large part of Russia is located in permafrost areas. These areas are widely used because there are concentrated valuable natural resources. Therefore to explore of cryosols it is important due to the significant increase of anthropogenic stress as well as the problem of global climate change. In the north of Western Siberia permafrost phenomena is widespread. Permafrost as a factor of soil formation and cryogenesis as a process have a great impact on the soil formation of these areas. Based on the research results of permafrost-affected soils tundra landscapes formed in the central part of the Tazovskiy Peninsula in cryogenic conditions, data were obtained which characterize the morphological features of soils. The specificity of soil cover distribution and manifestation of soil-forming processes within the study area are noted. Permafrost features such as frost cracking, cryoturbation, thixotropy, movement of humus are formed. The formation of these features is increased with the development of the territory. As a consequence, there is a change in the components of the environment and the destruction of the soil cover.

Keywords: Gleyed and nongleyed soils, permafrost, soil cryogenesis (pedocryogenesis), soil-forming macroprocesses.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1092237

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References:

[1] O.A. Anisimov, F.E. Nelson, "Permafrost distribution in the Northern Hemisphere under scenarios of climatic change”. Global Planet Change, 1996, pp. 59-72.
[2] V.O. Targulian, "Soil formation and weathering in cold humid regions (in Russian)”. Moscow, Nauka, 1971, 371 p.
[3] M.C. Serreze, J.E Walsh, F.S. Chapin, T. Osterkamp, M. Dyurgerov, V. Romanovsky, W.C. Oechel, J. Morison, T. Zhang, and R.G. Barry, "Observational evidence of recent change in the northern high-latitude environment”. Clim. Change, 2000, 46, pp. 159–207.
[4] M. Heimann, M. Reichstein, "Terrestrial ecosystem carbon dynamics and climate feedbacks”. Nature., 2008, vol. 451., pp. 289-292.
[5] T.V. Ananko, D.Ye. Komyushkov, Ye.M. Naumov, I.A. Sokolov, T.Ye. Yakusheva, "Soil Cryogenesis”. Soil-forming processes. Moscow, Dokuchaev Soil Science Institute, 2006, pp. 144-166.
[6] B.M. Klenov, G.D. Chimitdorzhieva, "Influence of continental climate on humification and elemental composition of humic acids of automorphic soils of Siberia”. Siberian Journal of Ecology, 2011, 5, pp. 665-671.
[7] U.F. Miko, Kirschbaum, "The temperature dependence of soil organic matter decomposition, and the effect of global warming on soil organic matter” Soil Biol. Biochem., 1995, 6, vol. 27., pp. 753-760.
[8] I.S. Dobrovolskiy, G.V. Urusevskaya, "Soil Geography”. Moscow, Moscow University, 2004, 460 p.
[9] I.M. Simonov, R.K. Sisco, "Yamal-Gydansk region. Climate (Russia)”. Leningrad, 1977, pp. 27-50.
[10] E.I. Valeyeva, D.V. Moskovchenko, "Zonal features regarding vegetation cover of the Taz Peninsula and its technogenic transformation”. Bulletin of Ecology, Forest Science and Landscape, 2008, 9, pp. 174-190.
[11] N.V. Kobeleva, "Large-scale ecological communities based on airphotos mapping and Gis-Technologies (For example, the central part of the Tazovskiy Peninsula)”, Proceedings of the Samara Scientific Center, Russian Academy of Science, 2012, 1(6), vol. 14., pp. 1607-1617.
[12] D.Ye. Komyushkov, I.A. Sokolov, "Soil and soil cover of the northern circumpolar region”. Eurasion soil science, 1998, 11, pp.1303-1317.
[13] V.N. Konischev, V.V. Rogov, "Influence of cryogenic on clay minerals”. Earth Cryosphere, 2008, 1, vol. 7, pp. 51-58.
[14] V.Ya. Khrenov, "Soils of Western Siberia Cryolithozone”. Novosibirsk. Nauka, 2011, 211 p.
[15] V.D. Tonkonogov, "Automorphic soil formation in the tundra and taiga zones of the East European and West Siberian plains” Moscow. Dokuchaev Soil Science Institute, 287 p. (2010).