Normal Stress‐Dependent Frictional Weakening of Large Rock Avalanche Basal Facies: Implications for the Rock Avalanche Volume Effect

Wang, Y. F.; Dong, Jia Jyun; Cheng, Qiangong

doi:10.1002/2018jb015602

Cited by 34 publications

(11 citation statements)

References 60 publications

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“…This may have affected its runout behavior as different evolutions of the friction coefficient may be associated with different thicknesses. Experiments have indeed demonstrated the control of normal stress on the friction coefficient as well as on the velocity‐dependent behavior in a wide range of stress and velocity (Boneh et al, 2013; Scaringi & Di Maio, 2016; Wang et al, 2018). Using a single parameter, a PD ‐dependent law can incorporate both the velocity‐dependent and normal stress‐dependent behaviors while tracking the evolution of the landslide movement through time.…”

Section: Resultsmentioning

confidence: 99%

“…By fitting experimental data, Mizoguchi et al (2007) obtained an exponential‐decay equation for the friction coefficient of shear gouge:

μ = μ_{ss} + ((), μ_{p} - μ_{ss}) \cdot e^{\frac{\ln (0.05) \cdot d}{D_{c}}}

where μ p and μ ss are the peak and steady‐state friction coefficients, respectively, d is the shear displacement of the specimen, and D c is the slip‐weakening distance. An exponential decrease of μ ss with the shear velocity (velocity‐dependent law) was observed, yet some experiments also identified a similar dependence on the normal stress (Boneh et al, 2013; Wang et al, 2018). Therefore, μ ss can be generally expressed as

μ_{ss} = A + B e^{Cξ}

where ξ represents either the velocity ( v ) or the normal stress and A , B , and C are fitting parameters.…”

Section: Introductionmentioning

confidence: 84%

“…where μ p and μ ss are the peak and steady-state friction coefficients, respectively, d is the shear displacement of the specimen, and D c is the slip-weakening distance. An exponential decrease of μ ss with the shear velocity (velocity-dependent law) was observed, yet some experiments also identified a similar dependence on the normal stress (Boneh et al, 2013;Wang et al, 2018). Therefore, μ ss can be generally expressed as…”

Section: Introductionmentioning

confidence: 92%

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An Empirical Power Density‐Based Friction Law and Its Implications for Coherent Landslide Mobility

Deng

Yan

Scaringi

et al. 2020

Geophysical Research Letters

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The evolution of the shear resistance at the base of a coherent landslide body can effectively control its dynamic behavior. High‐velocity rotary shear experiments have allowed scientists to explore stress‐strain conditions close to those found in large landslides and faults. These experiments have led to two alternative models being proposed, which describe the evolution of the shear resistance through friction laws that depend either on normal stress or on velocity. Here, we discuss an integrated approach, first proposed to study seismic fault behavior, that reconciles these two models under a single parameter—the power density—which we utilize for the first time to investigate landslide dynamics. Using thermodynamic and process‐based considerations, different soil and rock types can be related to different weakening mechanisms, which in turn can determine different landslide behaviors.

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Section: Resultsmentioning

confidence: 99%

“…By fitting experimental data, Mizoguchi et al (2007) obtained an exponential‐decay equation for the friction coefficient of shear gouge:

μ = μ_{ss} + ((), μ_{p} - μ_{ss}) \cdot e^{\frac{\ln (0.05) \cdot d}{D_{c}}}

μ_{ss} = A + B e^{Cξ}

where ξ represents either the velocity ( v ) or the normal stress and A , B , and C are fitting parameters.…”

Section: Introductionmentioning

confidence: 84%

Section: Introductionmentioning

confidence: 92%

See 1 more Smart Citation

An Empirical Power Density‐Based Friction Law and Its Implications for Coherent Landslide Mobility

Deng

Yan

Scaringi

et al. 2020

Geophysical Research Letters

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“…Many dynamic mechanisms have been proposed to explain the hypermobility of rock avalanches. Some mechanisms involve fluid media, such as air (Kent, 1966), water (Wang et al, 2002;Hungr and Evans, 2004), a fluid-like fine grain matrix (Hsü, 1975), melted rock or vapour (Habib, 1975;Goguel, 1978;Hu et al, 2018), and thermal pressurization and thermal moisture fluidization (Wang et al, 2017(Wang et al, , 2018a. Others invoke the interactions of materials in rock avalanche systems, such as shearing and impacting between a sliding mass and undulate path-generated acoustic fluidization (Melosh, 1979;Collins and Melosh, 2003), shearing between a rock mass and the ground (Foda, 1994;Wang et al, 2015), shearing between particles in the basal layer (Preuth et al, 2010), momentum transfer caused by the collisions of particles or different parts of the rock mass (Heim, 1932;Van Gassen et al, 1989;Miao et al, 2001), and dispersive pressure caused by dynamic fragmentation (Davies et al, 1999;Davies and McSaveney, 2009).…”

Section: Introductionmentioning

confidence: 99%

Multiscale effects caused by the fracturing and fragmentation of rock blocks during rock mass movement: implications for rock avalanche propagation

Lin

Wang

Xie

et al. 2022

Nat. Hazards Earth Syst. Sci.

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Abstract. The fracturing and fragmentation of rock blocks are important phenomena that occur ubiquitously during the propagation of rock avalanches. Here, the movement of a rectangular rock block characterized by different joint sets along an upper sloped and lower horizontal plane is simulated using discrete element method (DEM) models. The pattern of the joint set allows the block to break along weak joint planes at the onset of fragmentation. With this design, the fracturing and fragmentation of the sliding rock block and their influences on the conversion and transmission of energy within the system are investigated. The results show that rock fragmentation can significantly alter the horizontal velocities and kinetic energies of fragments in the block system, accelerating the front sub-block while decelerating the rear sub-block. Such energy conversion and transmission between the front and rear sub-blocks are attributed to the accumulation and release of elastic strain energy caused by fragmentation. The energy transfer induced by fragmentation is more efficient than that induced by collision. Furthermore, positive relationships between the kinetic energy increase in the front sub-block induced by joint fracturing and the joint strength can be reliably fitted with linear functions, indicating that a rock mass with a higher joint strength experiences more-energetic fragmentation effects.

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“…These hypotheses include bulk fluidisation or lubrication by air, gas, water, ice, heating or acoustic waves (see, e.g. references in Shreve 1987 ; Goren et al 2010 ; Ferri et al 2011 ; Bulmer 2012 ; Liu et al 2015 ; Mitchell et al 2015 ; Charrière et al 2016 ; Johnson et al 2016 ; Wang et al 2018 ), or the presence of an erodible bed (e.g. Mangeney et al 2010 ; Crosta et al 2009 , 2015 ; Iverson et al 2011 ; Farin et al 2014 ).…”

Section: Introductionmentioning

confidence: 99%

Empirical investigation of friction weakening of terrestrial and Martian landslides using discrete element models

et al. 2019

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Understanding what controls the travelling distance of large landslides has been the topic of considerable debate. By combining observation and experimental data with depth-averaged continuum modelling of landslides and generated seismic waves, it was empirically observed that lower effective friction had to be taken into account in the models to reproduce the dynamics and runout distance of larger volume landslides. Moreover, such simulation and observation results are compatible with a friction weakening with velocity as observed in earthquake mechanics. We investigate here as to whether similar empirical reduced friction should be put into discrete element models (DEM) to reproduce observed runout of large landslides on Earth and on Mars. First we show that, in the investigated parameter range and for a given volume, the runout distance simulated by 3D DEM is not much affected by the number (i.e. size) of grains once this number attains ~ 8000. We then calibrate the model on laboratory experiments and simulate other experiments of granular flows on inclined planes, making it possible for the first time to reproduce the observed effect of initial volume and aspect ratio on runout distances. In particular, the normalised runout distance starts to depend on the volume involved only above a critical slope angle > 16–19°, as observed experimentally. Finally, based on field data (volume, topography, deposit), we simulate a series of landslides on simplified inclined topography. The empirical friction coefficient, calibrated to reproduce the observed runout for each landslide, is shown to decrease with increasing landslide volume (or velocity), going down to values as low as 0.1–0.2. No distinguishable difference is observed between the behaviour of terrestrial and Martian landslides. Electronic supplementary material The online version of this article (10.1007/s10346-019-01140-8) contains supplementary material, which is available to authorized users.

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Normal Stress‐Dependent Frictional Weakening of Large Rock Avalanche Basal Facies: Implications for the Rock Avalanche Volume Effect

Cited by 34 publications

References 60 publications

An Empirical Power Density‐Based Friction Law and Its Implications for Coherent Landslide Mobility

An Empirical Power Density‐Based Friction Law and Its Implications for Coherent Landslide Mobility

Multiscale effects caused by the fracturing and fragmentation of rock blocks during rock mass movement: implications for rock avalanche propagation

Empirical investigation of friction weakening of terrestrial and Martian landslides using discrete element models

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