Reconstruction of Soil Particle Composition During Freeze-Thaw Cycling: A Review

Studies conducted over several decades have shown that the freeze-thaw cycles are a process of energy input and output in soil, which help drive the formation of soil structure, through water expansion by crystallization and the movement of water and salts by thermal gradients. However, most of thes...

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Bibliographic Details
Published inPedosphere Vol. 26; no. 2; pp. 167 - 179
Main Authors ZHANG, Ze, MA, Wei, FENG, Wenjie, XIAO, Donghui, HOU, Xin
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.04.2016
State Key Laboratory of Frozen Soil Engineering, Cold and Arid Regions Environmental and Engineering Research Institute, Chinese Academy of Sciences, Lanzhou 730000(China)
Subjects
aggregate stability
aggregation
crystallization
fragmentation
freeze-thaw cycles
freezing
mineral content
mineral particle
particle size
process energy
researchers
salts
soil aggregation
soil formation
soil granulometric composition
soil structure
temperature profiles
thawing
冻结过程
冻融循环
团聚体稳定性
土壤结构
土壤颗粒组成
循环过程
粒度组成
颗粒聚集
aggregate stability
aggregation
mineral particle
soil structure
fragmentation
soil granulometric composition
Online AccessGet full text
ISSN1002-0160
2210-5107
DOI10.1016/S1002-0160(15)60033-9

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Summary:Studies conducted over several decades have shown that the freeze-thaw cycles are a process of energy input and output in soil, which help drive the formation of soil structure, through water expansion by crystallization and the movement of water and salts by thermal gradients. However, most of these studies are published in Russian or Chinese and are less accessible to international researchers. This review brought together a wide range of studies on the effects of freezing and thawing on soil structure. The following findings are summarized: i) soil structure after freeze-thaw cycles changes considerably and the changes are due to the mechanical fragmentation of soil coarse mineral particles and the aggregation of soil fine particles; ii) the particle size of soil becomes homogeneous and the variation in soil structure weakens as the number of freeze-thaw cycles increases; iii) in the freezing process of soil, an important principle in the variation of soil particle bonding is presented as: condensation →aggregation→ crystallization; iv) the freeze-thaw cycling process has a strong effect on soil structure by changing the granulometric composition of mineral particles and structures within the soil. The freeze-thaw cycling process strengthens particle bonding, which causes an overall increase in aggregate stability of soil, showing a process from destruction to reconstruction.
Bibliography:aggregate stability, aggregation, fragmentation, mineral particle, soil granulometric composition, soil structure
32-1315/P
Studies conducted over several decades have shown that the freeze-thaw cycles are a process of energy input and output in soil, which help drive the formation of soil structure, through water expansion by crystallization and the movement of water and salts by thermal gradients. However, most of these studies are published in Russian or Chinese and are less accessible to international researchers. This review brought together a wide range of studies on the effects of freezing and thawing on soil structure. The following findings are summarized: i) soil structure after freeze-thaw cycles changes considerably and the changes are due to the mechanical fragmentation of soil coarse mineral particles and the aggregation of soil fine particles; ii) the particle size of soil becomes homogeneous and the variation in soil structure weakens as the number of freeze-thaw cycles increases; iii) in the freezing process of soil, an important principle in the variation of soil particle bonding is presented as: condensation →aggregation→ crystallization; iv) the freeze-thaw cycling process has a strong effect on soil structure by changing the granulometric composition of mineral particles and structures within the soil. The freeze-thaw cycling process strengthens particle bonding, which causes an overall increase in aggregate stability of soil, showing a process from destruction to reconstruction.
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ISSN:1002-0160
2210-5107
DOI:10.1016/S1002-0160(15)60033-9