Soil freezing and thawing processes affected by the different landscapes in the middle reaches of Heihe River Basin, Gansu, China

Soil freezing and thawing processes affected by the different landscapes in the middle reaches of Heihe River Basin, Gansu, China

•Combined NMM and TDR techniques is practical to calculate soil ice content.•The calculated soil ice content is corresponded well with other monitoring variables.•The freezing cycles were the greatest for farmland, followed by forest and desert.•Soil frozen processes benefit on soil water conservati...

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Published in:Journal of hydrology (Amsterdam) Vol. 519; pp. 1328 - 1338
Main Authors: Yi, Jun, Zhao, Ying, Shao, Ming’an, Zhang, Jianguo, Cui, Lele, Si, Bingcheng
Format: Journal Article
Language:English
Published: Kidlington Elsevier B.V 01-11-2014
Elsevier
Subjects:
Earth sciences
Earth, ocean, space
Exact sciences and technology
Farmlands
Forests
Freezing
Freshwater
Frost depth
Frozen soils
Hydrogeology
Hydrology
Hydrology. Hydrogeology
Landscapes
Melting
Moisture content
Soil (material)
Soil temperature
Soil water content
Thawing
Gansu China
Far East
Asia
Northwest China
China
China, People's Rep., Heihe R. basin
China, People's Rep
Frost depth
Thawing
Soil water content
Freezing
Soil temperature
physical properties
ground water
soil water
ice
time domain reflectometry
land use
aquifers
temperature
water content
heat flux
soils
climate change
landscapes
rivers
thawing
water table
seepage
forests
deserts
depth
freezing
hydrologic cycle
evaporation
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Summary:•Combined NMM and TDR techniques is practical to calculate soil ice content.•The calculated soil ice content is corresponded well with other monitoring variables.•The freezing cycles were the greatest for farmland, followed by forest and desert.•Soil frozen processes benefit on soil water conservation for all landscapes. An understanding of soil freezing and thawing processes in seasonally frozen soil is important for many agricultural and environmental issues, especially under different landscapes in terms of land use and climate change. In this study, sandy soil behavior under soil freezing and thawing cycles were investigated under three typical landscapes (i.e., farmland, forest, and desert) in the middle reaches of the Heihe River Basin, Northwest China, from December 2011 to May 2012. Both Neutron Moisture Meter and Time Domain Reflectometry techniques were used to investigate the total soil water content (TSWC) and liquid soil water content (LSWC), respectively, and further based on to calculate soil ice content (SIC) and ice ratio (IR). The partition TSWC into LSWC and SIC at different depths is shown to be corresponded well with soil temperature, frost depth and groundwater dynamics, provided a vigorous basis for augmenting the limited data on soil water redistribution in seasonally frozen soils under natural conditions of different landscapes. The greatest freezing cycles were observed for the farmland, characterized with the deepest frost depths (106cm), the highest IR (>0.9), and the largest upward heat fluxes (120Wm−2), followed by the forest, and then the desert. These differences were primarily attributed to landscape-dependent initial soil water content, soil surface cover and groundwater levels, with marginal effect being attributed to soil physical properties. Profiled water redistribution upon soil freezing and thawing was obviously observed in the moist forest, but neither in the wettest farmland or in the driest desert. The soil frozen processes had a beneficial effect on soil water conservation with reduced evaporation and seepage, and high water content maintained, which could be useful for plant germination in the following spring.
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content type line 23
ISSN:0022-1694
1879-2707
DOI:10.1016/j.jhydrol.2014.08.042