Ultralow Friction of Carbonate Faults Caused by Thermal Decomposition

Han, Raehee; Shimamoto, Toshihiko; Hirose, Takehiro; Ree, Jin-Han; Ando, Jun–ichi

doi:10.1126/science.1139763

Cited by 386 publications

(327 citation statements)

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“…The strength and corresponding stress drop of an asperity may greatly exceed the respective mean values for the whole rupture surface-depending on asperity size relative to rupture area of the earthquake [e.g., Somerville et al, 1999;Mai and Beroza, 2002;Ripperger and Mai, 2004;Kanamori and Brodsky, 2004;Konca et al, 2008;Mai and Thingbaijam, 2014]. Indeed, the inferred coseismic stress drops on those asperities [e.g., Ripperger and Mai, 2004;Mai and Thingbaijam, 2014] compare well with stress drops suggested by high-speed laboratory friction experiments [e.g., Kanamori and Brodsky, 2004;Han et al, 2007;Di Toro et al, 2011]. We conclude that laboratory friction experiments portray "only" the rupture behavior of strength asperities.…”

Section: Geophysical Research Letterssupporting

confidence: 60%

“…The corresponding values of Δτ are centered at 3-4 MPa and do not change systematically with earthquake size, which is taken as evidence for self-similar earthquake scaling [e.g., Kanamori and Anderson, 1975;Hanks, 1977;Allmann and Shearer, 2009]. On the other hand, laboratory friction experiments indicate an almost complete breakdown in frictional resistance during sliding when coseismic slip velocities are reached [e.g., Han et al, 2007;Di Toro et al, 2011]. The observed large change in friction (typically Δμ ≥ 0.5) in such experiments, combined with effective normal stresses at seismogenic depths (σ eff ), yields coseismic stress drops Δτ = Δμσ eff that exceed those derived from seismological observations by multiples of 10.…”

Section: Background and Motivationmentioning

confidence: 99%

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Fault roughness and strength heterogeneity control earthquake size and stress drop

Zielke

Gális

Martin

2017

Geophysical Research Letters

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An earthquake's stress drop is related to the frictional breakdown during sliding and constitutes a fundamental quantity of the rupture process. High‐speed laboratory friction experiments that emulate the rupture process imply stress drop values that greatly exceed those commonly reported for natural earthquakes. We hypothesize that this stress drop discrepancy is due to fault‐surface roughness and strength heterogeneity: an earthquake's moment release and its recurrence probability depend not only on stress drop and rupture dimension but also on the geometric roughness of the ruptured fault and the location of failing strength asperities along it. Using large‐scale numerical simulations for earthquake ruptures under varying roughness and strength conditions, we verify our hypothesis, showing that smoother faults may generate larger earthquakes than rougher faults under identical tectonic loading conditions. We further discuss the potential impact of fault roughness on earthquake recurrence probability. This finding provides important information, also for seismic hazard analysis.

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Section: Geophysical Research Letterssupporting

confidence: 60%

Section: Background and Motivationmentioning

confidence: 99%

Fault roughness and strength heterogeneity control earthquake size and stress drop

Zielke

Gális

Martin

2017

Geophysical Research Letters

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“…One of the most important findings in such experiments is the remarkable weakening due to mechano-chemical effects by frictional heating [Tullis, 2007]. Consequently, the following mechanisms have been proposed as contributing to weaker fault strength: melting, silicagel formation, thermal decomposition, moisture absorption/ desorption, and flash heating [Tsutsumi and Shimamoto, 1997;Goldsby and Tullis, 2002;Di Toro et al, 2004;Han et al, 2007;Mizoguchi et al, 2006].…”

Section: Introductionmentioning

confidence: 99%

Flash weakening is limited by granular dynamics

Kuwano

Hatano

2011

Geophys. Res. Lett.

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[1] We measured the steady-state friction coefficient of granite over a wide range of sliding velocities and pressures. We observed considerable weakening, described well by a flash-heating theory, above the sliding velocity of 1 cm/s regardless of pressure. At higher velocities, the velocity strengthening behavior replaced the velocity weakening behavior. This strengthening at higher velocities agrees with data from numerical simulations on sheared granular matter and is therefore described in terms of energy dissipation due to the inelastic deformation of grains. We propose a unified steady-state friction law that well describes the velocity and pressure dependence of the steady-state friction coefficient. Citation: Kuwano, O., and T. Hatano (2011), Flash weakening is limited by granular dynamics, Geophys. Res. Lett., 38, L17305,

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“…These mechanisms are thermal pressurization of pore fluid (thermal expansion), degradation of microcontacts by flash heating, thermal decomposition of rock minerals, lubrication by silica gel, and shear melting [e.g., Lin et al, 2001;Di Toro et al, 2004;Rice, 2006;Han et al, 2007]. These all involve heating of the shear zone and hence are plausible only under dynamic conditions (i.e., high slip velocity).…”

Section: Theories For Dynamic Weakening Of the Slip Surfacementioning

confidence: 99%

“…[87] Thermal decomposition results from frictional heating of rock minerals within narrow fault zones that are sheared at high velocities (i.e., 1 m/s [Han et al, 2007]). Very low friction appears to be associated with flash heating of an ultrafine decomposition product composed of nanometric particles, which exhibit degraded microcontacts.…”

Section: Thermal Decomposition Of Rock Mineralsmentioning

confidence: 99%

Rock‐and‐soil avalanches: Theory and simulation

Taboada

Estrada

2009

J. Geophys. Res.

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[1] We present a 2-D Contact Dynamics discrete element model for simulating initiation and motion of rock avalanches, integrating hillslope geometry, Mohr-Coulomb rock behavior, pore pressure before avalanche triggering, and avalanche trigger. Avalanche motion is modeled as a dense granular flow of dry frictional and cohesive particles. On the basis of granular physics and shear experiments, we review some of the theories for the unexpectedly long runout of rock avalanches. Different causes are evoked, according to the strength (strong or weak) of the slip surface relative to the bulk. ''Mechanical fluidization'' and ''acoustic fluidization'' theories state that agitation of rock particles reduces frictional strength, increasing runout. Conversely, granular mechanics suggests that, as ''shear-strain'' rate increases, granular material becomes more agitated, more dissipative, and more resistant. Another theory states that dynamic fragmentation of clasts creates an isotropic pressure that drives longer runout. In contrast, granular mechanics suggests that fragmentation may induce fluidization and strengthening of the granular material, while particle size reduction (among others) induces weakening of the granular flow and enhances long runout. Runout is also enhanced for column-like rock masses collapsing from steep hillslopes. Long runout may also be linked to thermal weakening mechanisms at the slip surface (e.g., thermal pressurization, and shear melting), which may lower drastically the shear strength. The model is illustrated with a hypothetical example of a rain-triggered avalanche, mobilizing shallowly dipping layers. Several phases are identified, including slope failure, avalanche triggering resulting from slip weakening, and avalanche motion in which rocks are folded and sheared.

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Ultralow Friction of Carbonate Faults Caused by Thermal Decomposition

Cited by 386 publications

References 20 publications

Fault roughness and strength heterogeneity control earthquake size and stress drop

Fault roughness and strength heterogeneity control earthquake size and stress drop

Flash weakening is limited by granular dynamics

Rock‐and‐soil avalanches: Theory and simulation

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