The landslide problem

Shanmugam, G.; Wang, Yuan

doi:10.3724/sp.j.1261.2015.00071

Cited by 147 publications

(51 citation statements)

References 254 publications

(339 reference statements)

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“…Slopes, whether subaerial or subaqueous, are inherently unstable because the sediments deposited on them are subjected to gravitational forces along an inclined surface (Posamentier & Martinsen, ). Moreover, subaqueous landslides can be much larger than those on land (Cruden, ; Pope et al, ; Shanmugam, ). Several possible mechanisms have been proposed to account for the vast subaqueous landslides (Galloway et al, ; Lewis, ).…”

Section: Discussionmentioning

confidence: 99%

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Giant sublacustrine landslide in the Cretaceous Songliao Basin, NE China

Pan

Liu

et al. 2019

Basin Research

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Mass failure deposits in lacustrine settings are some of the most understudied facies associations in the ancient or modern rock record. We integrated seismic data and well logs to investigate the external morphology, internal architecture and deformation and reservoir distribution of the sublacustrine landslides in the Cretaceous Nengjiang Formation of the Songliao Basin (SLB). A large‐scale sublacustrine landslide, named the Qi‐Jia sublacustrine landslide (QJSL), has been identified in the Nengjiang Formation of the SLB. The QJSL is currently the largest known sublacustrine landslide in the world. This landslide covers an area that exceeds 300 km2, with an estimated volume of 30 km3. Seismic imaging and mapping reveal that the QJSL can be recognized by several distinguishing seismic characteristics: discontinuous and internal chaotic seismic facies, compressional structures in the downslope region, irregular top and basal surfaces and erosional grooves in basal shear surfaces. The QJSL is 20–200 m thick, and is composed of a succession of fine‐grained deposits. Sandy layers are present but sparse and thinner than 16 m, and form reservoirs of the petroleum discoveries in this area. Our analyses show that the mechanism that triggered the collapse of the QJSL is attributed to rapid deposition and deltaic progradation. This study demonstrates that sand‐rich sublacustrine landslides formed at delta front slope can serve as conventional reservoirs in the lake centre, and provide a new target for subaqueous hydrocarbon exploration and development.

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Section: Discussionmentioning

confidence: 99%

“…Consequently, identifying a single process responsible for triggering a collapse is very difficult (Moscardelli, Wood, & Mann, ). Two or more of these processes could be acting at the same time (Moscardelli et al, ; Ogiesoba & Hammes, ; Shanmugam, ).…”

Section: Discussionmentioning

confidence: 99%

Giant sublacustrine landslide in the Cretaceous Songliao Basin, NE China

Pan

Liu

et al. 2019

Basin Research

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“…Maximum velocities are attained at the break of slope, followed by a decrease of velocity been visualized in great detail with sidescan sonar and multibeam echosounder, whereas corings have provided rich samples of oceanic sediments, allowing to distinguish genuine landside deposits from other sediments such as turbidites (Locat and Lee 2002). The ratio H/L for subaqueous landslide deposits may reach extremely low values, demonstrating that subaqueous landslides are more mobile than their subaerial counterparts (e.g., Locat and Lee 2002;De Blasio et al 2006;Shanmugam 2015). Because water exerts a strong drag hindrance on a fast-moving landslide (Eq.…”

Section: Discussionmentioning

confidence: 99%

“…Because water exerts a strong drag hindrance on a fast-moving landslide (Eq. (6) in Appendix 2 shows that the drag increases with the square of the velocity), it follows that submarine mass flows travel exploiting a phenomenon like hydroplaning (Mohrig et al 1998) capable of outcompeting the drag force (e.g., De Blasio 2011b;Shanmugam 2015).…”

Section: Discussionmentioning

confidence: 99%

Inferring the high velocity of landslides in Valles Marineris on Mars from morphological analysis

2016

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The flow characteristics and velocities of three landslides in Valles Marineris on Mars are investigated using detailed morphological analyses of high-resolution images and dynamical calculations based on the run-up and curvature of the landslide deposits. The morphologies of the landslides are described, especially concerning those characteristics that can provide information on the dynamics and velocity. The long runout and estimated high velocities, often exceeding 100 m/s, confirm a low basal friction experienced by these landslides. Because subaqueous landslides on Earth exhibit reduced friction, we explore the scenario of sub-lacustrine failures, but find little support to this hypothesis. The environmental conditions that better explain the low friction and the presence of longitudinal furrows suggest an aerial environment with a basal soft and naturally lubricating medium on which friction diminished gradually; in this perspective, ice is the most promising candidate.

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“…Real-world debris flows include additional complexity as they erode and entrain material along the bottom and sides of the slope with the downstream flow. We take these issues as motivational for the present work and refer the reader to the recent review of Delannay et al (2017) for further insight on granular flows and Shanmugam (2015) for heterogenous flows. The fundamentals physics of such flows is presented in Iverson (1997).…”

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confidence: 99%

Comparing thixotropic and Herschel–Bulkley parameterizations for continuum models of avalanches and subaqueous debris flows

Jeon

Hodges

2018

Nat. Hazards Earth Syst. Sci.

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Abstract. Avalanches and subaqueous debris flows are two cases of a wide range of natural hazards that have been previously modeled with non-Newtonian fluid mechanics approximating the interplay of forces associated with gravity flows of granular and solid-liquid mixtures. The complex behaviors of such flows at unsteady flow initiation (i.e., destruction of structural jamming) and flow stalling (restructuralization) imply that the representative viscositystress relationships should include hysteresis: there is no reason to expect the timescale of microstructure destruction is the same as the timescale of restructuralization. The nonNewtonian Herschel-Bulkley relationship that has been previously used in such models implies complete reversibility of the stress-strain relationship and thus cannot correctly represent unsteady phases. In contrast, a thixotropic nonNewtonian model allows representation of initial structural jamming and aging effects that provide hysteresis in the stress-strain relationship. In this study, a thixotropic model and a Herschel-Bulkley model are compared to each other and to prior laboratory experiments that are representative of an avalanche and a subaqueous debris flow. A numerical solver using a multi-material level-set method is applied to track multiple interfaces simultaneously in the simulations. The numerical results are validated with analytical solutions and available experimental data using parameters selected based on the experimental setup and without post hoc calibration. The thixotropic (time-dependent) fluid model shows reasonable agreement with all the experimental data. For most of the experimental conditions, the HerschelBulkley (time-independent) model results were similar to the thixotropic model, a critical exception being conditions with a high yield stress where the Herschel-Bulkley model did not initiate flow. These results indicate that the thixotropic relationship is promising for modeling unsteady phases of debris flows and avalanches, but there is a need for better understanding of the correct material parameters and parameters for the initial structural jamming and characteristic time of aging, which requires more detailed experimental data than presently available.

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The landslide problem

Cited by 147 publications

References 254 publications

Giant sublacustrine landslide in the Cretaceous Songliao Basin, NE China

Giant sublacustrine landslide in the Cretaceous Songliao Basin, NE China

Inferring the high velocity of landslides in Valles Marineris on Mars from morphological analysis

Comparing thixotropic and Herschel–Bulkley parameterizations for continuum models of avalanches and subaqueous debris flows

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