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01-08-2018 | Original Article

Rainfall-induced landslide in the active frontal fold–thrust belt of Northwestern Himalaya, Jammu: dynamics inferred by geological evidences and Ground Penetrating Radar

Authors: Yudhbir Singh, Ahsan Ul Haq, G. M. Bhat, S. K. Pandita, Arjun Singh, Rameshwar Sangra, Gulzar Hussain, S. S. Kotwal

Published in: Environmental Earth Sciences | Issue 16/2018

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Abstract

Landslides are the most established geological hazards in the frontal fold–thrust belt of Northwestern Himalaya comprising of Siwaliks and Murree strata. The continuous rainfall from 2 to 6 September, 2014 caused a massive landslide at village Sadal in Udhampur district of Jammu and Kashmir state. The landslide occurred in the early morning of September 6, 2014, destroying entire Sadal habitation comprising 45 houses, and killing 41 people and more than 500 domestic animals. Google earth images of pre and post-landslide events along with the field measurements show the kinematics of upper and lower parts of the slide. Horizontal and vertical components of displacement and mode of failure suggest the landslide as of complex nature. The shallow subsurface geophysical imaging through Ground Penetrating Radar (GPR) survey shows the failure plane composed of friable mudstone bed underlain by massive mudstone and overlain by cross-bedded sandstone. The depth of debris material above the failure plane ranges from 6 m at Site S1a-b to 10 m at Site-S2b and 20 m at Site S3a. The velocity analysis of Site-3 shows four thick layers represented from bottom to surface by L1—sandstone (V = 0.16 m/ns, travel time = 356.36 ns), L2—mudstone (V = 0.17 m/ns, travel time = 288.48 ns), L3—massive mudstone (V = 0.19 m/ns, travel time 220.68 ns), and L4—cross-laminated sandstone (V = 0.20 m/ns, travel time = 77.58 ns) overlaying the failure plane. The study shows the landslide occur along the western limb of a fold identified during the present work. We mapped an old landslide on the same limb which shows 5–6 m-thick subsurface debris material with thick rock fragments involved in the landslide process. The detailed geological and geophysical investigations suggest that both the landslides were triggered by extreme rain fall events.

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Title: Rainfall-induced landslide in the active frontal fold–thrust belt of Northwestern Himalaya, Jammu: dynamics inferred by geological evidences and Ground Penetrating Radar
Authors: Yudhbir Singh
Ahsan Ul Haq
G. M. Bhat
S. K. Pandita
Arjun Singh
Rameshwar Sangra
Gulzar Hussain
S. S. Kotwal
Publication date: 01-08-2018
Publisher: Springer Berlin Heidelberg
Published in: Environmental Earth Sciences / Issue 16/2018
Print ISSN: 1866-6280
Electronic ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-018-7772-0

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