Impact of dynamic desiccation cracks on hydrological processes and stability in expansive clay slopes: A coupled dual-permeability modeling approach

IF 8.4 1区工程技术 Q1 ENGINEERING, GEOLOGICAL

Engineering Geology Pub Date : 2025-10-01 DOI:10.1016/j.enggeo.2025.108377

Yi Luo , Jiaming Zhang , Chao-Sheng Tang , Guosheng Jiang , Thom Bogaard

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Abstract

Preferential flow and soil strength degradation induced by desiccation cracks are important causes for expansive clay slope instability. The cyclic opening and closing of desiccation cracks during drying-wetting processes incessantly alters preferential flow paths and soil strength. Quantify the impact of desiccation crack dynamics on slope hydrology and stability remains a major unresolved challenge. To bridge this gap, we developed the first slope-scale hydro-mechanical model that couples weather-driven crack evolution with preferential flow while incorporating the deterioration effect on soil strength. This unified approach is a major contribution to our capacity to model the integration of hydrological processes and mechanical degradation of soil strength induced by dynamic cracks. The hydrological part adopted a dynamic dual-permeability model (dynamic DPM) and was validated by a physical slope model test. The dynamic DPM was then integrated into a set of numerical slope stability analyses under one-year atmospheric conditions. The groundwater level, water balance, pore water distribution, crack evolution and slope stability were investigated in the case of dynamic cracks and fixed cracks. The hydrological results showed that the slope model with dynamic cracks retained more water and higher groundwater level than that with fixed cracks. The narrowing of desiccation cracks slows down slope drainage process, resulting in a rapid build-up of pore water pressure due to preferential flow, which emerges as an often overlooked and significant factor contributing to slope instability. Conversely, fixed and well-connected cracks in soils enhance water drainage and thus benefit slope stability. The mechanical results revealed that the irreversible deterioration effect induced by crack dynamics on soil strength persistently degrades long-term slope stability. These findings provide new insights into failure mechanisms in cracked soil slopes, and show the importance of the integration of dynamic crack properties into climate-resilient slope design. Also, our results underscore the importance of understanding and quantifying the physical behavior of soil structures for soil hydrological response and slope stability assessment.

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动态干燥裂缝对膨胀粘土边坡水文过程和稳定性的影响：一种耦合双渗透模型方法

干燥裂缝引起的优先流动和土体强度退化是膨胀性粘土边坡失稳的重要原因。在干湿过程中，干湿裂缝的循环开闭不断改变着优先流道和土体强度。量化干燥裂缝动力学对边坡水文和稳定性的影响仍然是一个主要的未解决的挑战。为了弥补这一差距，我们开发了第一个坡尺度的水力学模型，该模型将天气驱动的裂缝演化与优先流动结合起来，同时考虑了土壤强度的劣化效应。这种统一的方法对我们模拟水文过程和动力裂缝引起的土壤强度机械退化的综合能力作出了重大贡献。水文部分采用动态双渗透模型（dynamic DPM），并通过物理斜坡模型试验进行验证。然后将动态DPM整合到一组一年大气条件下的边坡稳定性数值分析中。研究了动态裂缝和固定裂缝情况下的地下水位、水平衡、孔隙水分布、裂缝演化和边坡稳定性。水文结果表明，含动力裂缝的边坡模型比含固定裂缝的边坡模型保留更多的水分和更高的地下水位。干燥裂缝的缩小减缓了边坡排水过程，由于优先流动导致孔隙水压力迅速积聚，这是一个经常被忽视的重要因素，导致边坡失稳。相反，土壤中固定且连接良好的裂缝加强了排水，从而有利于边坡的稳定。力学结果表明，裂缝动力对土体强度的不可逆劣化效应持续恶化边坡的长期稳定性。这些发现为裂缝土边坡的破坏机制提供了新的见解，并显示了将动态裂缝特性整合到气候适应型边坡设计中的重要性。此外，我们的研究结果强调了理解和量化土壤结构的物理行为对土壤水文响应和边坡稳定性评估的重要性。

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来源期刊

Engineering Geology 地学-地球科学综合

CiteScore

13.70

自引率

12.20%

发文量

327

审稿时长

5.6 months

期刊介绍： Engineering Geology, an international interdisciplinary journal, serves as a bridge between earth sciences and engineering, focusing on geological and geotechnical engineering. It welcomes studies with relevance to engineering, environmental concerns, and safety, catering to engineering geologists with backgrounds in geology or civil/mining engineering. Topics include applied geomorphology, structural geology, geophysics, geochemistry, environmental geology, hydrogeology, land use planning, natural hazards, remote sensing, soil and rock mechanics, and applied geotechnical engineering. The journal provides a platform for research at the intersection of geology and engineering disciplines.