Effects of normal stress variations on frictional stability of a fluid‐infiltrated fault

Chambon, Guillaume; Rudnicki, John W.

doi:10.1029/2001jb900002

Cited by 26 publications

(23 citation statements)

References 27 publications

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“…The observation that with constant fluid pressure, slip events occur during the lateral relaxation paths and not the axial compression paths indicate decreasing normal stress and shear stress promote accelerated slip. This result can be explained by previous experimental observations and analyses which show that decreasing normal stress can cause unstable fault slip [ Linker and Dieterich , ; Dieterich and Linker , ; Chambon and Rudnicki , ; He and Wong , ]. The instability is shown to occur because a decrease in the effective normal stress causes an immediate decrease in the friction coefficient and, therefore, shear stress ( τ = μ ( σ n − P f )) that is analogous to the direct effect in velocity‐stepping tests followed by an increase in friction coefficient to steady state.…”

Section: Discussionsupporting

confidence: 51%

Fault slip controlled by stress path and fluid pressurization rate

French

Zhu

Banker

2016

Geophysical Research Letters

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The practice of injecting fluids into the crust is linked to regional increases in seismicity. Increasing fluid pressure along preexisting faults is believed to enhance seismicity rates by reducing the shear stress required for slip, but the processes that cause faults to slip under conditions of fluid pressurization are poorly constrained. We use experimental rock deformation to investigate the controls of fluid pressurization and pressurization rates on fault slip style. We show that pore fluid pressurization is less effective that mechanical changes in fault normal stress at initiating accelerated slip events. Fluid pressurization enhances the total slip, slip velocity, and shear stress drop of events initiated by mechanical changes in normal stress, and these parameters are correlated with pressurization rate, but not the magnitude of fluid pressure. This result is consistent with field‐scale observations and indicates that processes active at the pore network scale affect induced seismicity.

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Section: Discussionsupporting

confidence: 51%

Fault slip controlled by stress path and fluid pressurization rate

French

Zhu

Banker

2016

Geophysical Research Letters

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“…Nevertheless, if the stability of the slip solution is assumed to evolve monotonically with the drainage parameter ϵ from the drained to the undrained limit, then it is likely that equation (22) is a sufficient condition for instability for arbitrary drainage conditions (any ϵ > 0). This conjecture that stability depends monotonically on drainage does, however, require investigation; Chambon and Rudnicki [2001] give an example for a rate‐ and state‐dependent friction relation in which stability does not depend monotonically on a drainage parameter.…”

Section: Parametric Dependencementioning

confidence: 99%

Shear heating of a fluid‐saturated slip‐weakening dilatant fault zone: 2. Quasi‐drained regime

Garagash

Rudnicki

2003

J. Geophys. Res.

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[1] This paper analyzes slip on a fluid-infiltrated dilatant fault for imposed (tectonic) strain rates much slower than the rate of fluid exchange between the gouge zone and the surroundings and for exchange of heat slower than of fluid, typical of interseismic or most laboratory loading conditions. The limiting solution, corresponding to the infinitely rapid drainage rate, developed in the companion paper by Garagash and Rudnicki [2003], yielded unbounded slip acceleration for sufficiently large slip weakening of the fault. Analysis for rapid but finite drainage rates (quasi-drained condition) reveals two types of possible instability. The first is inertial instability (a seismic event) characterized by an unbounded slip rate and attributed to the destabilizing effects of shear heating and fault slip weakening. The second corresponds to loss of uniqueness and arises from the small pressure increase caused by shear heating for rapid but finite rates of drainage. This instability emerges for even small amounts of thermomechanical coupling and a large range of dilatancy and slip weakening. Its resolution probably requires a more elaborate frictional description (e.g., rate and state), but within the slip-weakening framework here, leads to either slip arrest or inertial instability. The response is always unstable (in one of these two ways) for sufficiently large thermal coupling or initial stress regardless of the amount of slip weakening and dilatancy. The counterintuitive stabilizing effect of increased slip weakening or decreased dilatancy, similar to the effect in the companion paper, also occurs for nearly drained slip.

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“…Several numerical studies [ Lockner and Byerlee , 1995; Segall and Rice , 1995; Miller et al , 1996; Sleep , 1997; Taylor and Rice , 1998; Miller et al , 1999; Chambon and Rudnicki , 2001; Fitzenz and Miller , 2001] outlined principal mechanical implications of crustal pore pressure regimes in excess of hydrostatic. To pursue previous work, we focus on the role of dilatancy in active faulting [ Lockner and Byerlee , 1994; Rudnicki and Chen , 1988; Chambon and Rudnicki , 2001] and investigate effects of hydromechanical properties on spatiotemporal slip evolution of a two‐dimensional (2‐D) vertical strike‐slip fault plane embedded in a homogeneous half‐space. More specifically, we apply the formalism of a single degree of freedom elastohydraulic model developed by Segall and Rice [1995] to the geometry of an extended 2‐D fault plane used by Rice [1993] and in other purely elastic models [ Tse and Rice , 1986; Ben‐Zion and Rice , 1995, 1997; Rice and Ben‐Zion , 1996].…”

Section: Introductionmentioning

confidence: 99%

Stability regimes of a dilatant, fluid‐infiltrated fault plane in a three‐dimensional elastic solid

Hillers

Miller

2006

J. Geophys. Res.

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[1] We investigate in a systematic parameter space study dilatant effects on slip evolution of a fluid-infiltrated fault in the continuum limit. The fault is governed by rate-and state-dependent friction and an empirical law for porosity evolution. We focus on the response of systems as a function of fluid-related parameters, such as the degree of overpressurization, dilatancy and diffusivity. This study emphasizes the exploration of the parameter space for homogeneous along-strike properties to investigate the evolution of spatiotemporal slip depending on hydromechanical processes. Three types of responses emerge. First, system-wide unstable stick-slip develops for drained conditions, and for undrained conditions if mechanisms leading to an increase in pore space are less effective. The critical stiffness depends on hydraulic diffusivity and dilatancy, which is shown to correspond with interevent times of simulated stick-slip events. During instabilities the evolution of hydraulic variables differ significantly between drained and undrained conditions. Second, stable creep is a result of dilatant processes. Third, systems situated in transitional stability regimes develop nonuniform slip pattern in space and time, revealing a possible explanation for rupture termination and observed stable afterslip. Although these patterns are produced by models located in transition zones of the parameter space, the occurrence of heterogeneous slip evolution is persistent for an extensive range of parameter values. Since transition zones contain an broad range of plausible conditions in the crust, they do not represent extreme cases.Citation: Hillers, G., and S. A. Miller (2006), Stability regimes of a dilatant, fluid-infiltrated fault plane in a three-dimensional elastic solid,

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Effects of normal stress variations on frictional stability of a fluid‐infiltrated fault

Cited by 26 publications

References 27 publications

Fault slip controlled by stress path and fluid pressurization rate

Fault slip controlled by stress path and fluid pressurization rate

Shear heating of a fluid‐saturated slip‐weakening dilatant fault zone: 2. Quasi‐drained regime

Stability regimes of a dilatant, fluid‐infiltrated fault plane in a three‐dimensional elastic solid

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