Regularities of soil temperature changes during the period with snow cover in modern climatic conditions of the Eurasian Subarctic

Authors

Keywords:

snow thickness, air temperature, soil temperature, spatial distribution, long-term variation
Supporting Agencies
This work was supported by the Russian Foundation for Basic Research (project No. 20-55-00007 (collection, processing and primary analysis of baseline information)), as well as with the support of the Program of Fundamental Research of State Academies of Sciences (state task No. 0148-2019-0009 (interpretation of analysis results)).

Abstract

The influence of snow cover on the dynamics of soil temperature in the modern climatic conditions of the Eurasian Subarctic was investigated through a quantitative assessment of the features of the seasonal and long-term variation of parameters. Seasonal and long-term values of soil temperature for stable snow period decrease from west to east: a decrease of snow thickness and air temperature from west to east of Eurasia leads to a weakening of the heat-insulating properties of the snow cover with a significant decrease in regional air temperatures. With the emergence of a stable snow cover, the soil temperature seasonal and long-term standard deviation sharply decreases compared to the autumn and spring periods. With the appearance of snow cover, the soil temperature standard deviation drops sharply compared to the autumn and spring periods. An exception is the northeast of Siberia: here, a relatively small thickness of snow determines a noticeable dependence of the course of soil temperature on the dynamics of surface air temperature. There are no significant long-term trends in soil temperature due to its low variability during winter period. Analysis of the course of the studied characteristics anomalies showed an insignificant and non-systematic number of their coincidences. Currently, we have not found similar research results for large regions. The revealed patterns can be used in the analysis of the results of monitoring the state of the land surface, in the development of remote sensing algorithms, in the refinement of predictive scenarios of environmental changes.

Author Biography

  • Lev M. Kitaev, Institute of Geography, Russian Academy of Sciences, 29 Staromonetny Lane, Moscow 119017, Russia

    PhD (geography); senior researcher at the laboratory of climatology

References

  1. L’vovich MI. Voda i zhizn’: vodnye resursy, ikh preobrazovanie i okhrana [Water and life: water resources, their transformation and protection]. Moscow: Mysl’; 1986. 254 p. Russian.
  2. Nikolaev AN, Skachkov YuB. Snow cover and permafrost soil temperature influence on the radial growth of trees in Central Yakutia. Journal of Siberian Federal University. Biology. 2012;5(1):43–51. Russian.
  3. Kudryavtsev VA. Temperatura verkhnikh gorizontov vechnomerzloi tolshchi v predelakh SSSR [The temperature of the upper layers of permafrost in the USSR]. Moscow: Publishing House of the Academy of Sciences of USSR; 1954. 182 p. Russian.
  4. Pavlov AV. Monitoring kriolitozony [Permafrost monitoring]. Novosibirsk: Geo; 2008. 230 p. Russian.
  5. Osokin NI, Sosnovskiy AV. Impact of dynamics of air temperature and snow cover thickness on the ground freezing. Earth’s Cryosphere. 2015;19(1):99–105. Russian.
  6. Sleptsov VI, Mordovskoi SD, Petrov EE. [Calculating the number of freeze-thaw cycles of the rock mass conditions for the Central Yakutia on horizontal surfaces]. Mining Informational and Analytical Bulletin. 2012;9:99–103. Russian.
  7. Sherstyukov AB. Correlation of soil temperature with air temperature and snow cover depth in Russia. Earth’s Cryosphere. 2008;12(1):79–87. Russian.
  8. Sherstyukov AB, Anokhin YuA. [Spatial features of air and soil temperature changes in the permafrost zone of Russia]. In: Izrael’YuA, editor. Nauchnye aspekty ekologicheskikh problem Rossii. Trudy II Vserossiiskoi konferentsii; 29–31 maya 2006 g.; Moskva, Rossiya [Scientific aspects of environmental problems in Russia. Proceedings of the 2nd All-Russian conference; 2006 May 29–31; Moscow, Russia]. Moscow: Nauka; 2006. p. 22–23. Russian.
  9. Kitaev LM, Ableeva VA, Asainova ZA, Zheltukhin AS, Korobov ED. Seasonal dynamics of air temperature, snow storage and soil freezing in Central part of the East European Plain. Ice and Snow. 2017;57(4):518–526. Russian. DOI: 10.15356/2076-6734-2017-4-518-526.
  10. Kitaev LM, Ableeva VA, Korobov ED, Zheltukhin AS. [Long-term trends and interannual fluctuations in snow cover characteristics, climate and soil temperature of the East European Plain]. In: Nauchnye problemy ozdorovleniya rossiiskikh rek i puti ikh resheniya. Sbornik nauchnykh trudov Vserossiiskoi nauchnoi konferentsii s mezhdunarodnym uchastiem; 8–14 sentyabrya 2019 g.; Nizhnii Novgorod, Rossiya [Scientific problems of rehabilitation of Russian rivers and ways to solve them. Collection of scientific papers of the All-Russian scientific conference with international participation; 2019 September 8–14; Nizhny Novgorod, Russia]. Moscow: Studiya F1; 2019. p. 166–171. Russian.

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Published

2021-06-08

How to Cite

[1]
Kitaev, L.M. 2021. Regularities of soil temperature changes during the period with snow cover in modern climatic conditions of the Eurasian Subarctic. Journal of the Belarusian State University. Geography and Geology. 1 (Jun. 2021), 13–22. DOI:https://doi.org/10.33581/2521-6740-2021-1-13-22.