Estimation of the thermal resistance of snow cover based on the ground temperature

Climate changes have influence on the thermal stability of permafrost soils. The assessment of its changes should be made taking account of the parameters of the snow cover and its thermophysical characteristics. A method for determining the thermal resistance of snow cover and the effective coeffic...

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Bibliographic Details
Published in:Atmospheric Chemistry and Physics
Main Authors: V. Kotlyakov M., A. Sosnovsky V., В. Котляков М., А. Сосновский В.
Other Authors: The mathematical modeling and numerical experiments carried out according to the framework of fundamental scientific studies within the project reg. № 0148-2019-0004, processing of experimental data and their analysis supported by the RFBR, grant № 18-05-60067., Математическое моделирование и численные эксперименты проводилось в рамках темы Государственного задания № 0148-2019-0004, обработка архивных материалов и их анализ – при поддержке гранта РФФИ №18-05-60067.
Format: Article in Journal/Newspaper
Language:Russian
Published: IGRAS 2021
Subjects:
thermal resistance;snow cover;thermal conductivity;soil temperature;modeling
термическое сопротивление;снежный покров;теплопроводность;температура почвы;моделирование
Arctic
Yakutsk
permafrost
Yakutia
Online Access:https://ice-snow.igras.ru/jour/article/view/888
https://doi.org/10.31857/S2076673421020081
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Summary:Climate changes have influence on the thermal stability of permafrost soils. The assessment of its changes should be made taking account of the parameters of the snow cover and its thermophysical characteristics. A method for determining the thermal resistance of snow cover and the effective coefficient of thermal conductivity of snow based on ground temperature is proposed for areas of the Arctic zone of the Russian Federation with negative ground temperatures. From data on ground temperature measurements at depths of 20 and 40 cm obtained from hydrometeorological stations, it is possible to estimate the heat flow from the ground into the snow cover and, at a known air temperature and snow depth, to calculate the thermal resistance of the snow and the effective coefficient of thermal conductivity. In this case, the obtained value of the thermal conductivity coefficient of snow will include all the features of the snow cover development by the time of measurement. To develop a method for determining the thermal resistance of snow cover and the effective coefficient of thermal conductivity of snow, numerical experiments were performed using a mathematical model, which allowed establishing the conditions for the applicability of the method. The paper presents results of calculations of the thermal resistance and thermal conductivity of snow cover made by the proposed method for winters of 2006/07 and 2009/10 in Yakutia for the snow cover of different thickness composed mainly by semi-skeletal and skeletal crystals of deep frost, reaching a diameter of 3–5 mm. The use of this method for the conditions of the Yakutsk with a known type of snow formation confirmed its effectiveness. Предложена методика определения термического сопротивления снежного покрова и эффективного коэффициента теплопроводности снега по температуре грунта, температуре воздуха и толщине снежного покрова. Для отработки методики определения термического сопротивления снежного покрова и эффективного коэффициента теплопроводности снега выполнены ...

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