Rock slope instability assessment using spatially distributed structural orientation data in Darjeeling Himalaya (India)

Spaceborne radar interferometry is a powerful tool to characterize landslides at local and regional scales. However, its application to very slow rock slope deformations in alpine environments (displacement rates < 5 cm/year) remains challenging, mainly due to low signal to noise ratio, atmospheric disturbances, snow cover effects, and complexities resulting from heterogeneous displacement in space and time. Here we combine SqueeSARTM data, targeted multi-temporal baseline DInSAR, GPS data, and detailed field morpho-structural mapping, to unravel the kinematics, internal segmentation, and style of activity of the Mt. Mater deep-seated gravitational slope deformation (DSGSD) in Valle Spluga (Italy). We retrieve slope kinematics by performing 2D decomposition (2D InSAR) of SqueeSARTM products derived from Sentinel-1 data acquired in ascending and descending orbits. To achieve a spatially-distributed characterization of DSGSD displacement patterns and activity, we process Sentinel-1 A/B images (2016-2019) with increasing temporal baselines (ranging from 24-days to 1-year) and generate several multi-temporal interferograms. Unwrapped displacement maps are validated using ground-based GPS data. Interferograms derived with different temporal baselines reveal a strong kinematic and morpho-structural heterogeneity and outline nested rockslides and active sectors, that arise from the background displacement signal of the main DSGSD. Seasonal interferograms, supported by GPS displacement measurements, reveal non-linear displacement trends suggesting a complex response of different slope sectors to rainfall and snowmelt. Our analyses clearly outline a composite slope instability with different nested sectors possibly undergoing different evolutionary trends towards failure. The results herein outline the potential of a targeted use of DInSAR for the detailed investigation of very slow rock slope deformations in different geological and geomorphological settings.

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Assessment of Slope Instability and Risk Analysis of Road Cut Slopes in Lashotor Pass, Iran

Journal of Geological Research ◽

10.1155/2014/763598 ◽

2014 ◽

Vol 2014 ◽

pp. 1-12 ◽

Cited By ~ 3

Author(s):

Mohammad Hossein Taherynia ◽

Mojtaba Mohammadi ◽

Rasoul Ajalloeian

Keyword(s):

Rock Mass ◽

Risk Analysis ◽

Rock Slope ◽

Classification Systems ◽

Slope Instability ◽

Rock Slope Stability ◽

Rock Slopes ◽

The Stability ◽

Cut Slopes ◽

Road Cut Slopes

Assessment of the stability of natural and artificial rock slopes is an important topic in the rock mechanics sciences. One of the most widely used methods for this purpose is the classification of the slope rock mass. In the recent decades, several rock slope classification systems are presented by many researchers. Each one of these rock mass classification systems uses different parameters and rating systems. These differences are due to the diversity of affecting parameters and the degree of influence on the rock slope stability. Another important point in rock slope stability is appraisal hazard and risk analysis. In the risk analysis, the degree of danger of rock slope instability is determined. The Lashotor pass is located in the Shiraz-Isfahan highway in Iran. Field surveys indicate that there are high potentialities of instability in the road cut slopes of the Lashotor pass. In the current paper, the stability of the rock slopes in the Lashotor pass is studied comprehensively with different classification methods. For risk analyses, we estimated dangerous area by use of the RocFall software. Furthermore, the dangers of falling rocks for the vehicles passing the Lashotor pass are estimated according to rockfall hazard rating system.

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Identification of active release planes using ground-based differential InSAR at the Randa rock slope instability, Switzerland

Natural Hazards and Earth System Science ◽

10.5194/nhess-9-2027-2009 ◽

2009 ◽

Vol 9 (6) ◽

pp. 2027-2038 ◽

Cited By ~ 18

Author(s):

V. Gischig ◽

S. Loew ◽

A. Kos ◽

J. R. Moore ◽

H. Raetzo ◽

...

Keyword(s):

Rock Slope ◽

Hazard Analysis ◽

Failure Surface ◽

Accurate Estimate ◽

Slope Instability ◽

Lateral Release ◽

Rupture Plane ◽

Local Movement ◽

Active Release ◽

Displacement Patterns

Abstract. Five ground-based differential interferometric synthetic aperture radar (GB-DInSAR) surveys were conducted between 2005 and 2007 at the rock slope instability at Randa, Switzerland. Resultant displacement maps revealed, for the first time, the presence of an active basal rupture zone and a lateral release surface daylighting on the exposed 1991 failure scarp. Structures correlated with the boundaries of interferometric displacement domains were confirmed using a helicopter-based LiDAR DTM and oblique aerial photography. Former investigations at the site failed to conclusively detect these active release surfaces essential for kinematic and hazard analysis of the instability, although their existence had been hypothesized. The determination of the basal and lateral release planes also allowed a more accurate estimate of the currently unstable volume of 5.7±1.5 million m3. The displacement patterns reveal that two different kinematic behaviors dominate the instability, i.e. toppling above 2200 m and translational failure below. In the toppling part of the instability the areas with the highest GB-DInSAR displacements correspond to areas of enhanced micro-seismic activity. The observation of only few strongly active discontinuities daylighting on the 1991 failure surface points to a rather uniform movement in the lower portion of the instability, while most of the slip occurs along the basal rupture plane. Comparison of GB-DInSAR displacements with mapped discontinuities revealed correlations between displacement patterns and active structures, although spatial offsets occur as a result of the effective resolution of GB-DInSAR. Similarly, comparisons with measurements from total station surveys generally showed good agreement. Discrepancies arose in several cases due to local movement of blocks, the size of which could not be resolved using GB-DInSAR.

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Investigation of cusp catastrophe model of rock slope instability with general constitutive equations

Bulletin of Engineering Geology and the Environment ◽

10.1007/s10064-020-01946-0 ◽

2020 ◽

Vol 80 (1) ◽

pp. 303-315

Author(s):

Zhonghu Zhao ◽

Jieyang Xu ◽

Jiahao Yuan ◽

Wuyue Chang ◽

Guihong Guo

Keyword(s):

Constitutive Equations ◽

Rock Slope ◽

Slope Instability ◽

Cusp Catastrophe ◽

Catastrophe Model ◽

Cusp Catastrophe Model

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Thermomechanical forcing of deep rock slope deformation: 2. The Randa rock slope instability

Journal of Geophysical Research Atmospheres ◽

10.1029/2011jf002007 ◽

2011 ◽

Vol 116 (F4) ◽

Cited By ~ 29

Author(s):

Valentin S. Gischig ◽

Jeffrey R. Moore ◽

Keith F. Evans ◽

Florian Amann ◽

Simon Loew

Keyword(s):

Rock Slope ◽

Slope Deformation ◽

Slope Instability ◽

Deep Rock

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Stability assessment of degrading permafrost rock slopes based on a coupled thermo-mechanical model

10.5194/esurf-2020-70 ◽

2020 ◽

Author(s):

Philipp Mamot ◽

Samuel Weber ◽

Saskia Eppinger, ◽

Michael Krautblatter

Keyword(s):

Slope Stability ◽

Rock Slope ◽

Fracture Network ◽

Slope Instability ◽

Rock Slope Stability ◽

Permafrost Degradation ◽

Rock Slopes ◽

High Mountains ◽

Permafrost Rock ◽

Wide Range

Abstract. In the last two decades, permafrost degradation has been observed to be a major driver of enhanced rock slope instability and associated hazards in high mountains. While the thermal regime of permafrost degradation in high mountains has already been intensively investigated, the mechanical consequences on rock slope stability have so far not been reproduced in numerical models. Laboratory studies and conceptual models argue that warming and thawing decrease rock and discontinuity strength and promote deformation. This study presents the first general approach for a temperature-dependent numerical stability model that simulates the mechanical response of a warming and thawing permafrost rock slope. The proposed procedure is applied to a rockslide at the permafrost-affected Zugspitze summit crest. Laboratory tests on frozen and unfrozen rock joint and intact rock properties provide material parameters for the discontinuum model developed with the Universal Distinct Element Code (UDEC). Geophysical and geotechnical field surveys deliver information on the permafrost distribution and fracture network. The model demonstrates that warming decreases rock slope stability to a critical level, while thawing initiates failure. A sensitivity analysis of the model with a simplified geometry and warming trajectory below 0 °C shows that progressive warming close to the melting point initiates instability above a critical slope angle of 50–62°, depending on the orientation of the fracture network. The increase in displacements intensifies for warming steps closer to zero degree. The simplified and generalised model can be applied to permafrost rock slopes (i) which warm above −4 °C, (ii), with ice-filled joints, (iii) with fractured limestone or probably most of the rock types relevant for permafrost rock slope failure, (iv) with a wide range of slope angles (30–70°) and orientations of the fracture network (consisting of three joint sets). The presented model is the first one capable of assessing the future destabilisation of degrading permafrost rock slopes.

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Multiple rock-slope failures from Mannen in Romsdal Valley, western Norway, revealed from Quaternary geological mapping and 10Be exposure dating

The Holocene ◽

10.1177/0959683618798165 ◽

2018 ◽

Vol 28 (12) ◽

pp. 1841-1854 ◽

Cited By ~ 13

Author(s):

Paula Hilger ◽

Reginald L Hermanns ◽

John C Gosse ◽

Benjamin Jacobs ◽

Bernd Etzelmüller ◽

...

Keyword(s):

Slope Failure ◽

Rock Slope ◽

Significant Risk ◽

Geological Mapping ◽

Slope Instability ◽

Permafrost Degradation ◽

Geomorphological Mapping ◽

Exposure Dating ◽

Western Norway ◽

Air Temperatures

Oversteepened valley walls in western Norway have high recurrences of Holocene rock-slope failure activity causing significant risk to communities and infrastructure. Deposits from six to nine catastrophic rock-slope failure (CRSF) events are preserved at the base of the Mannen rock-slope instability in the Romsdal Valley, western Norway. The timing of these CRSF events was determined by terrestrial cosmogenic nuclide dating and relative chronology due to mapping Quaternary deposits. The stratigraphical chronology indicates that three of the CRSF events occurred between 12 and 10 ka, during regional deglaciation. Congruent with previous investigations, these events are attributed to the debuttressing effect experienced by steep slopes following deglaciation, during a period of paraglacial relaxation. The remaining three to six CRSF events cluster at 4.9 ± 0.6 ka (based on 10 cosmogenic 10Be samples from boulders). CRSF events during this later period are ascribed to climatic changes at the end of the Holocene thermal optimum, including increased precipitation rates, high air temperatures and the associated degradation of permafrost in rock-slope faces. Geomorphological mapping and sedimentological analyses further permit the contextualisation of these deposits within the overall sequence of post-glacial fjord-valley infilling. In the light of contemporary climate change, the relationship between CRSF frequency, precipitation, air temperature and permafrost degradation may be of interest to others working or operating in comparable settings.

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Reconstruction of the long-term evolution of a catastrophic slope failure at the Preonzo rock slope instability complex (TI, Switzerland)

Landslides and Engineered Slopes. Experience, Theory and Practice ◽

10.1201/b21520-122 ◽

2016 ◽

pp. 1027-1034 ◽

Cited By ~ 1

Author(s):

S Gschwind ◽

S Loew

Keyword(s):

Slope Failure ◽

Rock Slope ◽

Long Term Evolution ◽

Slope Instability ◽

Term Evolution

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Linking weathering and rock slope instability: non-linear perspectives

Earth Surface Processes and Landforms ◽

10.1002/esp.3294 ◽

2012 ◽

Vol 38 (1) ◽

pp. 62-70 ◽

Cited By ~ 33

Author(s):

Heather A. Viles

Keyword(s):

Rock Slope ◽

Slope Instability ◽

Non Linear

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Repeat Glacier Collapses and Surges in the Amney Machen Mountain Range, Tibet, Possibly Triggered by a Developing Rock-Slope Instability

Remote Sensing ◽

10.3390/rs11060708 ◽

2019 ◽

Vol 11 (6) ◽

pp. 708 ◽

Cited By ~ 6

Author(s):

Frank Paul

Keyword(s):

Satellite Data ◽

Temperature Increase ◽

Rock Slope ◽

Slope Instability ◽

Mountain Range ◽

Rock Slopes ◽

Direct Response ◽

Hill Slope ◽

Eastern Tibet ◽

Regional Temperature

Collapsing valley glaciers leaving their bed to rush down a flat hill slope at the speed of a racing car are so far rare events. They have only been reported for the Kolkaglacier (Caucasus) in 2002 and the two glaciers in the Aru mountain range (Tibet) that failed in 2016. Both events have been studied in detail using satellite data and modeling to learn more about the reasons for and processes related to such events. This study reports about a series of so far undocumented glacier collapses that occurred in the Amney Machen mountain range (eastern Tibet) in 2004, 2007, and 2016. All three collapses were associated with a glacier surge, but from 1987 to 1995, the glacier surged without collapsing. The later surges and collapses were likely triggered by a progressing slope instability that released large amounts of ice and rock to the lower glacier tongue, distorting its dynamic stability. The surges and collapses might continue in the future as more ice and rock is available to fall on the glacier. It has been speculated that the development is a direct response to regional temperature increase that destabilized the surrounding hanging glaciers. However, the specific properties of the steep rock slopes and the glacier bed might also have played a role.

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