The Critical Depth of Freeze-Thaw Soil under Different Types of Snow Cover

Snow cover is the most common upper boundary condition influencing the soil freeze-thaw process in the black soil farming area of northern China. Snow is a porous dielectric cover, and its unique physical properties affect the soil moisture diffusion, heat conduction, freezing rate and other variables. To understand the spatial distribution of the soil water-heat and the variable characteristics of the critical depth of the soil water and heat, we used field data to analyze the freezing rate of soil and the extent of variation in soil water-heat in a unit soil layer under bare land (BL), natural snow (NS), compacted snow (CS) and thick snow (TS) treatments. The critical depth of the soil water and heat activity under different snow covers were determined based on the results of the analysis, and the variation fitting curve of the difference sequences on the soil temperature and water content between different soil layers and the surface 5-cm soil layer were used to verify the critical depth. The results were as follows: snow cover slowed the rate of soil freezing, and the soil freezing rate under the NS, CS and TS treatments decreased by 0.099 cm/day, 0.147 cm/day and 0.307 cm/day, respectively, compared with that under BL. In addition, the soil thawing time was delayed, and the effect was more significant with increased snow cover. During freeze-thaw cycles, the extent of variation in the water and heat time series in the shallow soil was relatively large, while there was less variation in the deep layer. There was a critical stratum in the vertical surface during hydrothermal migration, wherein the critical depth of soil water and heat change gradually increased with increasing snow cover. The variance in differences between the surface layer and both the soil water and heat in the different layers exhibited “steady-rising-steady” behavior, and the inflection point of the curve is the critical depth of soil freezing and thawing. This critical layer is a demarcation point between frozen soil and non-frozen soil, delineating the boundary between soil water and heat migration and non-migration. Furthermore, with increasing snow cover thickness and increasing density, the critical depth gradually increased.

[1]  Q. Shao,et al.  Influences of climate variation on thawing-freezing processes in the northeast of Three-River Source Region China , 2013 .

[2]  K. Larsen,et al.  Repeated freeze-thaw cycles and their effects on biological processes in two arctic ecosystem types , 2002 .

[3]  H. Shibata,et al.  Effects of freeze–thaw cycles resulting from winter climate change on soil nitrogen cycling in ten temperate forest ecosystems throughout the Japanese archipelago , 2014 .

[4]  G. Flerchinger,et al.  Freezing and thawing processes , 2005 .

[5]  H. Gärtner,et al.  Effect of permafrost on the formation of soil organic carbon pools and their physical–chemical properties in the Eastern Swiss Alps , 2013 .

[6]  Toshio Koike,et al.  The soil moisture distribution, thawing–freezing processes and their effects on the seasonal transition on the Qinghai–Xizang (Tibetan) plateau , 2003 .

[7]  Qingbai Wu,et al.  Exchange of groundwater and surface‐water mediated by permafrost response to seasonal and long term air temperature variation , 2011 .

[8]  Shi Haibin,et al.  Characteristics of air temperature and water-salt transfer during freezing and thawing period , 2007 .

[9]  B. Si,et al.  Soil freezing–thawing characteristics and snowmelt infiltration in Cryalfs of Alberta, Canada , 2015 .

[10]  Shi Hai-bin Study on water-heat-salt transfer in soil freezing-thawing based on Simultaneous Heat and Water model , 2009 .

[11]  Nikolay I. Shiklomanov,et al.  Subsidence risk from thawing permafrost , 2001, Nature.

[12]  S. Morin,et al.  Numerical and experimental investigations of the effective thermal conductivity of snow , 2011 .

[13]  L. Ya,et al.  Characteristics of soil freeze–thaw cycles and their effects on water enrichment in the rhizosphere , 2016 .

[14]  S. Ge,et al.  Groundwater in the Tibet Plateau, western China , 2008 .

[15]  Houzhen Wei,et al.  Freezing and thawing characteristics of frozen soils: Bound water content and hysteresis phenomenon , 2014 .

[16]  P. He,et al.  Cyclic freeze–thaw as a mechanism for water and salt migration in soil , 2015, Environmental Earth Sciences.

[17]  C. Potter Predicting climate change effects on vegetation, soil thermal dynamics, and carbon cycling in ecosystems of interior Alaska , 2004 .

[18]  F. Nelson,et al.  Active‐layer mapping at regional scales: a 13‐year spatial time series for the Kuparuk region, north‐central Alaska , 2002 .

[19]  Fan Jihu The Freezing-Thawing Processes and Soil Moisture-Energy Distribution in Permafrost Active Layer,Northern Tibet , 2014 .

[20]  P. Bonnaventure,et al.  A Permafrost Probability Model for the Southern Yukon and Northern British Columbia, Canada , 2012 .

[21]  S. Hasegawa,et al.  Influence of rain, air temperature, and snow cover on subsequent spring-snowmelt infiltration into thin frozen soil layer in northern Japan , 2011 .

[22]  C. Voss,et al.  Analytical solutions for benchmarking cold regions subsurface water flow and energy transport models: one-dimensional soil thaw with conduction and advection , 2014 .