含水率对粉质黏土滑带土抗剪强度影响的微观机理研究

    MICRO-MECHANISM UNDERLYING THE INFLUENCE OF MOISTURE CONTENT ON THE SHEAR STRENGTH OF SILTY CLAY SLIDING ZONE SOIL

    • 摘要: 滑带土是滑坡的重要组成部分,其抗剪强度具有显著的水力-力学耦合依赖性。尽管已有研究揭示了含水率与宏观力学性质的经验关系,然而水分诱发抗剪强度劣化的微观跨尺度作用机制尚未充分阐明。本研究联合采用X射线衍射(XRD)、大型三轴剪切试验、滤纸法及扫描电镜(SEM)技术,系统表征了滑带土趋于饱和含水率过程中(11% ~19%)的矿物组成、基质吸力演化规律及多尺度微观结构响应,并解析了含水率-强度衰减的微观力学链式机制。结果表明:(1)基质吸力随含水率增加呈非线性衰减,临界吸力阈值触发吸力-强度关系由非线性向拟线性转变,导致抗剪强度骤降;(2)微观结构分析表明,颗粒间胶结失效、孔隙网络重构及黏土矿物水化膨胀等多尺度劣化机制协同作用,是宏观强度骤降的微观诱因。上述发现从多尺度水力-力学耦合视角,揭示了滑带土含水率依赖性强度劣化的内在机制,为滑坡稳定性评估提供了理论依据。

       

      Abstract: The sliding zone soil,a critical component controlling landslide stability,exhibits shear strength that is highly dependent on water content. Although previous studies have extensively explored the macroscopic relationship between water content and mechanical properties,the micro-mechanisms governing moisture-induced shear strength deterioration remain unclear. The purpose of this study is to unravel the microscale interactions between water content variations and shear strength reduction in sliding zone soils. Methods including X-ray diffraction(XRD),large-scale triaxial tests,the filter paper method,and scanning electron microscopy(SEM)were employed to systematically analyze mineral composition,matric suction,microstructure,and shear strength under water contents ranging from natural(11%)to saturated(19%)conditions. The results demonstrated that: (1)matric suction decreased with increasing water content,and a critical suction threshold triggered a transition from a nonlinear to an approximately linear suction-strength correlation,accompanied by a sudden drop in shear strength; (2)multi-scale microstructural deterioration mechanisms revealed by SEM analysis showed that the synergistic effects of intergranular contact weakening and pore connectivity evolution induced a secondary abrupt shear strength reduction in sliding zone soils. In conclusion,the abrupt shear strength reduction is attributed to the combined effects of suction loss beyond the critical threshold and microscale fabric weakening. These findings enhance the mechanistic understanding of landslide reactivation under hydrological changes.

       

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