Soil freezing process and different expressions for the soil-freezing characteristic curve

Pub Date : 2018-11-23 DOI:10.3724/SP.J.1226.2017.00221
Junping Ren, S. Vanapalli, Zhong Han
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引用次数: 28

Abstract

The soil-freezing characteristic curve (SFCC), which represents the relationship between unfrozen water content and sub-freezing temperature (or suction at ice-water interface) in a freezing soil, can be used for understanding the transportation of heat, water, and solute in frozen soils. In this paper, the soil freezing process and the similarity between the SFCC of saturated frozen soil and soil-water characteristic curve (SWCC) of unfrozen unsaturated soil are reviewed. Based on similar characteristics between SWCC and SFCC, a conceptual SFCC is drawn for illustrating the main features of soil freezing and thawing processes. Various SFCC expressions from the literature are summarized. Four widely used expressions ( i.e. , power relationship, exponential relationship, van Genuchten 1980 equation and Fredlund and Xing 1994 equation) are evaluated using published experimental data on four different soils ( i.e. , sandy loam, silt, clay, and saline silt). Results show that the exponential relationship and van Genuchten (1980) equation are more suitable for sandy soils. The simple power relationship can be used to reasonably best-fit the SFCC for soils with different particle sizes; however, it exhibits limitations when fitting the saline silt data. The Fredlund and Xing (1994) equation is suitable for fitting the SFCCs for all soils studied in this paper.
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土壤冻结过程及其冻结特性曲线的不同表达式
土壤冻结特性曲线(SFCC)代表了冻土中未冻结含水量与亚冻结温度(或冰水界面吸力)之间的关系,可用于理解冻土中热量、水和溶质的传输。本文综述了土壤冻结过程,以及饱和冻土的SFCC与未冻非饱和土的土壤水分特征曲线(SWCC)的相似性。基于SWCC和SFCC的相似特性,提出了一个概念性的SFCC来说明土壤冻融过程的主要特征。总结了文献中的各种SFCC表达。使用已发表的四种不同土壤(即沙壤土、粉土、粘土和含盐粉土)的实验数据,评估了四种广泛使用的表达式(即幂关系、指数关系、van Genuchten 1980方程以及Fredlund和Xing 1994方程)。结果表明,指数关系和van-Genuchten(1980)方程更适用于砂土。对于不同粒径的土壤,可以使用简单的幂关系来合理地最佳拟合SFCC;然而,它在拟合含盐淤泥数据时表现出局限性。Fredlund和Xing(1994)方程适用于本文研究的所有土壤的SFCC。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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