Study of slope instability on the Bhaderwah–Bani Highway, Jammu and Kashmir, India

Journal of Palaeosciences Pub Date : 2019-12-31 DOI:10.54991/jop.2019.42

I. Farooq, G. Bhat, S. Pandita, R. Sangra, Arjun Singh, Gulzar Hussain, Y. Singh, Ahsan-ul-Haq

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Abstract

Northwest Himalaya has witnessed lot of mass movements during the Quaternary period which have led to palaeoenvironmental degradation and deposition of erratic size sediments. These sediments have developed as fossil slides along the mountain slopes. In last few decades, the frequency of landslides has increased due to various factors such as complex geology, geotechnical properties of the rocks and anthropogenic activities. The investigation of rock slopes require geo–engineering evaluation to assess the instability of critical slopes leading to landslides particularly in the Himalayan region, where rocks are highly folded, faulted, jointed and weathered. In the present study, a total of 15 rock slopes have been selected for rapid assessment of instability condition using rock mass rating basic (RMRb), slope mass rating (SMR) and kinematics analysis techniques along Bhaderwah–Bani Highway in Jammu and Kashmir. Field surveys were conducted regarding required input data collection followed by laboratory works. The results of RMRb show two classes of rock mass, i.e., Class II–Good (86.58%) and Class III–Fair (13.42%). The SMR index classify rock slopes into different stability class results, which infers completely unstable (L4 and L14), unstable (L1, L2, L3, L8, L9, L11, L12 and L13), partially stable (L5, L6 and L7) and stable (L10 and L15) categories. The final output of kinematic analysis verify different modes of structurally controlled slope failures i.e., planar (30.72%), wedge (57.6%) and toppling (11.52%), representing all 15 sites in the study area.

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印度查谟和克什米尔巴德瓦-巴尼公路边坡失稳研究

西北喜马拉雅地区在第四纪经历了大量的物质运动，导致了古环境的退化和不规则大小沉积物的沉积。这些沉积物是随着化石沿着山坡滑动而形成的。近几十年来，由于复杂的地质、岩石的岩土力学性质和人为活动等多种因素，滑坡的发生频率有所增加。岩石斜坡的调查需要地质工程评估，以评估导致滑坡的关键斜坡的不稳定性，特别是在喜马拉雅地区，那里的岩石高度折叠，断裂，节理和风化。在本研究中，选取了查谟和克什米尔巴德尔瓦-巴尼高速公路沿线的15个岩质边坡，利用岩体质量等级基础(RMRb)、边坡质量等级(SMR)和运动学分析技术进行了失稳状况的快速评估。进行实地调查，收集所需的输入资料，然后进行实验室工作。RMRb结果显示岩体分为2类，即II-Good(86.58%)和III-Fair(13.42%)。SMR指数将岩质边坡划分为不同的稳定性等级结果，分为完全不稳定(L4和L14)、不稳定(L1、L2、L3、L8、L9、L11、L12和L13)、部分稳定(L5、L6和L7)和稳定(L10和L15)等类别。运动学分析的最终输出验证了结构控制边坡破坏的不同模式，即平面(30.72%)、楔形(57.6%)和倾倒(11.52%)，代表了研究区所有15个站点。

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Journal of Palaeosciences

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