Rahul Verma
Pachhunga University College, India
Title: Failure mechanism of Rangwamual Landslide, Aizawl, Mizoram, India
Biography
Biography: Rahul Verma
Abstract
Mizoram is one of the most landslide prone states of India. Majority of the landslides in the state, are triggered by the natural factors like climate, physiography and geoenvironment. The prime causes of the landslides in the state can be listed as rugged topography, Tertiary sedimentary geology, steeper slopes, heavy rainfall and location in Seismic zone–V. The rock types of the region consist of sandstones and shales of Bhuban Formation of Surma Group (Middle Miocene), and are very prone to weathering & erosion and subsequent failure under external factors. The present case study pertains to the analyses of the “failure mechanism” of “Rangwamual Landslide” of Aizawl District of Mizoram, India which falls on the very strategic National Highway No.44 A, connecting Aizawl town to the state’s only airport at Lengpui. The slide location lies between latitudes 23º44´57.8”N and 23º45’02.8’’N and longitudes 92º41’40.76” and 92º41’42.51” E. The slide occurred in the first week of November; 2014. The failure mechanism of the present slide has been revealed on the basis of integrated analyses of field database using Survey of India Toposheet No.84 A/9 at 1:20000 scale and GIS database (Satellite Data IRS P6/ LISS4 -5.8 Mts. Resolution) using ARCGIS 9.3. Digital Elevation Model (DEM) and Triangulated Irregular Network (TIN) show a variation of elevation from lowest 593 to highest 1153 in the slide section. Both, TIN & DEM models clearly indicate that, from the central ridge, the maximum decline in elevation is in west south west and west direction. Beds also dip due west in general and the dip direction also coincides with the slope trend. The “rose diagram” plotted for the beds of the slide section, show a “mean direction of 272.8°. The slope generated with CARTOSAT digital elevation model with the help of Arc Map tools, also reveals maximum steepness of the slope from the central ridge, in the same mean direction. Intercalation of shale and sandstone as the prominent lithology, is found to dip due westward where the highway lies. The heavy monsoonal rainfall of more than 500 mm, between June to October, 2014, had triggered the slope disequilibrium and weakening of the slope material. The rain water seeped into the shale – sandstone contacts following the dip direction and it led to the reduction in cohesive strength by adding weight to the slope material and thereby reducing the angle of repose. The weakened slope material slided down under the conjugate factorial effect of dip, slope, lithological interface and rainfall.