Eurasian Journal of Soil Science
Volume 5, Issue 4, Oct 2016, Pages 279 - 284DOI: 10.18393/ejss.2016.4.279-284
Stable URL: http://ejss.fess.org/10.18393/ejss.2016.4.279-284
Copyright © 2016 The authors and Federation of Eurasian Soil Science Societies
Structural-functional concept of thermophysical condition of the soils of Altai Region
Article first published online: 28 Apr 2016 | How to cite | Additional Information (Show All)
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Makarychev, S., V. Bolotov, A., G.2016. Structural-functional concept of thermophysical condition of the soils of Altai Region. Eurasian J. Soil Sci. 5(4): 279 - 284. DOI : 10.18393/ejss.2016.4.279-284Author information
Sergey Makarychev , Altai State Agricultural University, Barnaul, RussiaAndrey Bolotov , Altai State Agricultural University, Barnaul, Russia
Publication information
Issue published online: 01 Oct 2016Article first published online : 28 Apr 2016
Manuscript Accepted : 25 Mar 2016
Manuscript Received: 08 Sep 2015
DOI: 10.18393/ejss.2016.4.279-284
Stable URL: http://ejss.fesss.org/10.18393/ejss.2016.4.279-284
Abstract
The goal of this study was to reveal the quantitative interrelations between the thermophysical indices (thermal conductivity and thermal diffusivity) and physical soil properties such as; moisture content, density and detachability. According to the research targets, the soil samples including different genesis and soil particle size distribution were taken in different soil and climatic zones of the Altai Region. These were the sod-podzolic sandy loam soils of the dry steppes, chernozems and chestnut soils of light and medium loamy particle size distribution of temperately arid zone, and the heavy loamy gray forest soils and clayey chernozems of the Altai foothills and low mountains. The samples of undisturbed structures in different soil horizons were studied. To measure the thermophysical properties in laboratory setting, a pulse method of a two-dimensional heat source was used. The method takes into account the patterns of temperature field equalization in an unbounded medium after the heat source termination. A feature of this process is the occurrence of peak temperature at the investigated point of the medium at a given instant. The knowledge of this temperature and time enables to determine the soil thermal capacity, thermal conductivity and thermal diffusivity.Keywords
Soil, soil-physical factors, thermal capacity, thermal conductivity, thermal diffusivity
Corresponding author
References
Arkhangelskaya, T. A., 2014. Diversity of thermal conditions within the paleocryogenic soil complexes of the East European Plain: The discussion of key factors and mathematical modeling. Geoderma 213: 608-616.
Bolotov, A.G., Makarychev, S.V., 2015. Hydrophysical properties of the soils of the south-east of West Siberia. ASAU Publishing Division. Barnaul, Russia. 129 pp. [in Russian].
Cudnovskiy, A.F., 1976. Soil thermal physics. Nauka. Moscow, Russia. 352 pp. [in Russian].
Ekberli, I., 2006. Determination of initial unconditional solution of heat conductivity equation for evaluation of temperature variance in finite soil layer. Journal of Applied Science 6(7): 1520- 1526.
Gülser, C., Ekberli, I., 2004. A Comparison of estimated and measured diurnal soil temperature through a clay soil depth. Journal of Applied Science 4(3): 418-423.
Kaye, G.W.C., Laby, T.H., 1995. Tables of physical and chemical constants. Longman. 16 th edition, UK. 611 pp.
Makarychev, S.V., Mazirov, M.A., 1996. Soil thermal physics: methodology and properties. Vol. 2. VRIA. Suzdal, Russia. 231 pp. [in Russian].
Mikayilov, F.D., Shein, E.V., 2010. Theoretical principles of experimental methods for determining the thermal diffusivity of soils. Eurasian Soil Science 43(5): 556–564.
Nerpin, S.V., Chudnovskiy, A.F., 1970. Physics of the soil (Translated from Russian, 1967) Isreal program for scientific translations, Keter Press, Jerusalem, Israel. pp.194–233.
Panfilov, V.P., Makarychev, S.V., Lunin, A.I., Tchashina, N.I., 1982. Some regularities of moisture-heat transfer in soils of different texture. Problems of Soil Science. Soviet pedologists to the XII International Congress of Soil Science, Moscow, Russia. p.13-18.
Voronin, A.D., 1984. Structural-functional hydrophysics of soils. MSU Publishing Division. Moscow, Russia. 204 pp. [in Russian].
Abstract
The goal of this study was to reveal the quantitative interrelations between the thermophysical indices (thermal conductivity and thermal diffusivity) and physical soil properties such as; moisture content, density and detachability. According to the research targets, the soil samples including different genesis and soil particle size distribution were taken in different soil and climatic zones of the Altai Region. These were the sod-podzolic sandy loam soils of the dry steppes, chernozems and chestnut soils of light and medium loamy particle size distribution of temperately arid zone, and the heavy loamy gray forest soils and clayey chernozems of the Altai foothills and low mountains. The samples of undisturbed structures in different soil horizons were studied. To measure the thermophysical properties in laboratory setting, a pulse method of a two-dimensional heat source was used. The method takes into account the patterns of temperature field equalization in an unbounded medium after the heat source termination. A feature of this process is the occurrence of peak temperature at the investigated point of the medium at a given instant. The knowledge of this temperature and time enables to determine the soil thermal capacity, thermal conductivity and thermal diffusivity.
Keywords: Soil, soil-physical factors, thermal capacity, thermal conductivity, thermal diffusivity.
References
Arkhangelskaya, T. A., 2014. Diversity of thermal conditions within the paleocryogenic soil complexes of the East European Plain: The discussion of key factors and mathematical modeling. Geoderma 213: 608-616.
Bolotov, A.G., Makarychev, S.V., 2015. Hydrophysical properties of the soils of the south-east of West Siberia. ASAU Publishing Division. Barnaul, Russia. 129 pp. [in Russian].
Cudnovskiy, A.F., 1976. Soil thermal physics. Nauka. Moscow, Russia. 352 pp. [in Russian].
Ekberli, I., 2006. Determination of initial unconditional solution of heat conductivity equation for evaluation of temperature variance in finite soil layer. Journal of Applied Science 6(7): 1520- 1526.
Gülser, C., Ekberli, I., 2004. A Comparison of estimated and measured diurnal soil temperature through a clay soil depth. Journal of Applied Science 4(3): 418-423.
Kaye, G.W.C., Laby, T.H., 1995. Tables of physical and chemical constants. Longman. 16 th edition, UK. 611 pp.
Makarychev, S.V., Mazirov, M.A., 1996. Soil thermal physics: methodology and properties. Vol. 2. VRIA. Suzdal, Russia. 231 pp. [in Russian].
Mikayilov, F.D., Shein, E.V., 2010. Theoretical principles of experimental methods for determining the thermal diffusivity of soils. Eurasian Soil Science 43(5): 556–564.
Nerpin, S.V., Chudnovskiy, A.F., 1970. Physics of the soil (Translated from Russian, 1967) Isreal program for scientific translations, Keter Press, Jerusalem, Israel. pp.194–233.
Panfilov, V.P., Makarychev, S.V., Lunin, A.I., Tchashina, N.I., 1982. Some regularities of moisture-heat transfer in soils of different texture. Problems of Soil Science. Soviet pedologists to the XII International Congress of Soil Science, Moscow, Russia. p.13-18.
Voronin, A.D., 1984. Structural-functional hydrophysics of soils. MSU Publishing Division. Moscow, Russia. 204 pp. [in Russian].