Study on the Mechanical Criterion of Ice Lens Formation Based on Pore Size Distribution

Study on the Mechanical Criterion of Ice Lens Formation Based on Pore Size Distribution

Ice lens is the key factor which determines the frost heave in engineering construction in cold regions. At present, several theories have been proposed to describe the formation of ice lens. However, most of these theories analyzed the ice lens formation from a macroscopic view and ignored the infl...

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Bibliographic Details
Published in:Applied sciences 2020-12, Vol.10 (24), p.8981
Main Authors: Liu, Yuhang, Li, Dongqing, Chen, Lei, Ming, Feng
Format: Article
Language:eng
Subjects:
Cold regions
Criteria
Crystallization
crystallization pressure
Energy
frost heave
Frost heaving
Hypotheses
Ice
Ice formation
ice lens
Lenses
Moisture content
Pore size
Pore size distribution
Porosity
Size distribution
Soil stresses
Statistics
Stress
Stress concentration
Temperature
unfrozen water content
Water content
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Summary:Ice lens is the key factor which determines the frost heave in engineering construction in cold regions. At present, several theories have been proposed to describe the formation of ice lens. However, most of these theories analyzed the ice lens formation from a macroscopic view and ignored the influence of microscopic pore sizes and structures. Meanwhile, these theories lacked the support of measured data. To solve this problem, the microscopic crystallization stress was converted into the macro mean stress through the principle of statistics with the consideration of pore size distribution. The mean stress was treated as the driving force of the formation of ice lens and induced into the criterion of ice lens formation. The influence of pore structure and unfrozen water content on the mean stress was analyzed. The results indicate that the microcosmic crystallization pressure can be converted into the macro mean stress through the principle of statistics. Larger mean stress means the ice lens will be formed easier in the soil. The mean stress is positively correlated with initial water content. At the same temperature, an increase to both the initial water content and the number of pores can result in a larger mean stress. Under the same initial water content, mean stress increases with decreasing temperature. The result provides a theoretical basis for studying ice lens formation from the crystallization theory.
ISSN:2076-3417
2076-3417