Remolding Water Content Effect on the Behavior of Frozen Clay Soils Subjected to Monotonic Triaxial Loading

Remolding Water Content Effect on the Behavior of Frozen Clay Soils Subjected to Monotonic Triaxial Loading

Understanding the mechanical behavior of frozen clay subgrade soils was essential for ensuring the safe and stable operation of transportation lines. However, the influence of remolding water content <i>w</i> on this behavior remained unclear. To address this gap, this study examined the...

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Bibliographic Details
Main Authors: Shuai Qi, Jinhui Liu, Wei Ma, Jing Wang, Houwang Bai, Shaojian Wang
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Applied Sciences
Subjects:
clay soils
frozen soils
remolding water content
soil microstructure
mechanical behavior
Online Access:https://www.mdpi.com/2076-3417/15/13/7590
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Summary:Understanding the mechanical behavior of frozen clay subgrade soils was essential for ensuring the safe and stable operation of transportation lines. However, the influence of remolding water content <i>w</i> on this behavior remained unclear. To address this gap, this study examined the effect of <i>w</i> through monotonic triaxial testing. Three typical remolding water contents (<i>w</i> = 19%, 27.5% and 35%) and three confining pressures (<i>σ</i><sub>3</sub> = 200 kPa, 700 kPa and 1200 kPa) were considered. Results showed that the mechanical behavior of frozen clay soils displayed a clear dependence on <i>w</i>, which was controlled by microstructural evolution. As <i>w</i> increased, the shear strength <i>q</i><sub>max</sub>, resilient modulus <i>E</i><sub>0</sub> and cohesion <i>c</i> increased, which resulted from the progressive development of ice bonding within the shear plane. A threshold <i>w</i> value was found at <i>w</i><sub>opt</sub> = 27.5%, marking a structural transition and separating the variations of <i>q</i><sub>max</sub>, <i>E</i><sub>0</sub> and <i>c</i> into two regimes. When <i>w</i> ≤ 27.5%, the soil fabric was controlled by clay aggregates. As <i>w</i> increased, the growth in ice cementation was confined within these aggregates, leading to limited increase in <i>q</i><sub>max</sub>, <i>E</i><sub>0</sub> and <i>c</i>. However, as <i>w</i> exceeded 27.5%, the soil fabric transitioned into a homogeneous matrix of dispersed clay particles. In this case, increasing <i>w</i> greatly promoted the development of an interconnected ice cementation network, thus significantly facilitating the increase in <i>q</i><sub>max</sub>, <i>E</i><sub>0</sub> and <i>c</i>. The friction angle <i>φ</i> decreased with <i>w</i> increasing, primarily due to the lubrication effect caused by the growing ice. In addition, the enhanced lubrication effect in the clay particle-dominated fabric (<i>w</i> > 27.5%) resulted in a larger reduction rate of <i>φ</i>. Regarding Poisson’s ratio <i>v</i> and dilation angle <i>ψ</i>, the <i>w</i> increase led to growth in both parameters. This phenomenon could be explained by the increased involvement of solid ice into the soil structure.
ISSN:2076-3417

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