On the evolution of elastic properties during laboratory stick‐slip experiments spanning the transition from slow slip to dynamic rupture

Tinti, Elisa; Scuderi, M. M.; Scognamiglio, Laura; Stefano, Giuseppe Di; Marone, Chris; Collettini, Cristiano

doi:10.1002/2016jb013545

Cited by 74 publications

(73 citation statements)

References 106 publications

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“…This wavelet represents the transducer response to the first arrival rather than the P-wave coda used by previous studies (eg. Scuderi et al, 2016;Singh et al, 2019), which represents accumulated effects of multiple reflections through frictional interfaces and the bulk ( Figure 4 in Tinti et al, 2016). For more detailed experimental methods, we refer readers to Shreedharan et al (2019) and Supporting Information S1.…”

Section: Methodsmentioning

confidence: 99%

Preseismic Fault Creep and Elastic Wave Amplitude Precursors Scale With Lab Earthquake Magnitude for the Continuum of Tectonic Failure Modes

Shreedharan

Bolton

Rivière

et al. 2020

Geophysical Research Letters

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Tectonic faults fail in a continuum of modes from slow earthquakes to elastodynamic rupture.Precursory variations in elastic wavespeed and amplitude, interpreted as indicators of imminent failure, have been observed in limited natural settings and lab experiments where they are thought to arise from contact rejuvenation and microcracking within and around the fault zone. However, the physical mechanisms and connections to fault creep are poorly understood. Here we vary loading stiffness during frictional shear to generate a range of slip modes and measure fault zone properties using transmitted elastic waves. We find that elastic wave amplitudes show clear changes before fault failure. The temporal onset of amplitude reduction scales with lab earthquake magnitude and the magnitude of this reduction varies with fault slip. Our data provide clear evidence of precursors to lab earthquakes and suggest that continuous seismic monitoring could be useful for assessing fault state and seismic hazard potential.Plain Language Summary Earthquakes in nature can occur slowly, over many days, or rapidly within a few seconds or minutes. In a few cases geoscientists have reported, in hindsight, "precursory" changes in seismic velocities, groundwater levels, and elastic wave attenuation that occurred prior to earthquakes. The ability to robustly identify these signals and accurately attribute them to imminent earthquakes could have a profound effect on our hazard preparedness, particularly for coastal communities where tsunamis occur. Here we study lab earthquakes and use acoustic pulses to image the faults. We show that elastic wave amplitude decreases systematically before failure, providing a clear precursor to failure. The magnitude of this lab earthquake precursor is related to the amount of pre-earthquake fault slip during both slow and fast laboratory earthquakes.

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Section: Methodsmentioning

confidence: 99%

Preseismic Fault Creep and Elastic Wave Amplitude Precursors Scale With Lab Earthquake Magnitude for the Continuum of Tectonic Failure Modes

Shreedharan

Bolton

Rivière

et al. 2020

Geophysical Research Letters

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“…Nevertheless, its thickness is linked with the softening response of the system, that is, the reduction of friction in function of slip, rate of slip, and other variables related to multiphysical couplings. This region of extreme shearing usually consisted of ultracataclastic materials, and it has a complex structure (Ben‐Zion & Sammis, ; Brodie et al, ) due to various physicochemical phenomena that take place during preseismic slip and coseismic slip (see Anthony & Marone, ; Rattez et al, , , ; Reches & Lockner, ; Scuderi et al, ; Tinti et al, , among others). As a result, the apparent friction, F , does not depend only on the extent and the rate of slip,

δ, v = \overset{δ}{true}

but also on the evolution of the microstructural network, the grain size, the presence and pressure of interstitial fluids, the temperature, time (state) and the reactivation of chemical reactions (Brantut & Sulem, ; Veveakis et al, , , among others).…”

Section: Steady‐state and Stability Conditions For The Spring‐slider mentioning

confidence: 99%

Controlling Anthropogenic and Natural Seismicity: Insights From Active Stabilization of the Spring‐Slider Model

Stefanou

2019

JGR Solid Earth

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We present a theoretical study focusing on exploring the possibility of controlling anthropogenic and natural seismicity. We actively control the pressure of injected fluids using a negative‐feedback control system. Our analysis is based on the spring‐slider model for modeling the earthquake instability. We use a general Coulomb‐type rheology for describing the frictional behavior of a fault system. This model leads to a nonautonomous system, whose steady state and stability are studied using a double‐scale asymptotic analysis. This approach renders the dominant order of the system time invariant. Established tools from the classical mathematical theory of control are used for designing a proper stabilizing controller. We show that the system is stabilizable by controlling fluid pressure. This is a central result for industrial operations. A stabilizing controller is then designed and tested. The controller regulates in real time the applied pressure in order to assure stability, avoid unwanted seismicity, and drive the system from unstable states of high potential energy, to stable ones of low energy. The controller performs well even in the absence of complete knowledge of the frictional properties of the system. Finally, we present two numerical examples (scenarios) and illustrate how anthropogenic and natural earthquakes could be, in theory, prevented.

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“…This stability transition, described in section 2, marks a balance between the rate of elastic energy release and the rate of frictional strength loss. Rich behavior that includes slow slip events has been demonstrated numerically [ Gu et al ., ; Rice and Gu , ] and experimentally [ Leeman et al ., ; Tinti et al ., ]. Continuous fault models have utilized transitional behavior to describe slow slip events [ Liu and Rice , , ] and both fast and slow ruptures on the same VW fault patch [e.g., Veedu and Barbot , ; Chen and Lapusta , ].…”

Section: Introductionmentioning

confidence: 99%

Slow and fast ruptures on a laboratory fault controlled by loading characteristics

2017

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Recent geodetic observations indicate that a single fault may slip slowly and silently or fast and seismically in different circumstances. We report laboratory experiments that demonstrate how the mode of faulting can alternate between fast “stick‐slip” events (70 to ~500 mm/s sliding rates) and slow silent events (~0.001 to 30 mm/s) as a result of loading conditions rather than friction properties or stiffness of the loading machine. The 760 mm long granite sample is close to the critical nucleation length scale for unstable slip, so small variations in nucleation properties result in measurable differences in slip events. Slow events occur when instability cannot fully nucleate before reaching the sample ends. Dynamic events occur after long healing times or abrupt increases in loading rate which suggests that these factors shrink the spatial and temporal extents of the nucleation zone. Arrays of slip, strain, and ground motion sensors installed on the sample allow us to quantify seismic coupling and study details of premonitory slip and afterslip. We find that seismic coupling decreases when slip rates fall below about 70 mm/s. The slow slip events we observe are primarily aseismic (less than 1% of the seismic coupling of faster events) and produce swarms of very small M −6 to M −8 events. These mechanical and seismic interactions suggest that faults with transitional behavior—where creep, small earthquakes, and tremor are often observed—could become seismically coupled if loaded rapidly, either by a slow slip front or dynamic rupture of an earthquake that nucleated elsewhere.

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On the evolution of elastic properties during laboratory stick‐slip experiments spanning the transition from slow slip to dynamic rupture

Cited by 74 publications

References 106 publications

Preseismic Fault Creep and Elastic Wave Amplitude Precursors Scale With Lab Earthquake Magnitude for the Continuum of Tectonic Failure Modes

Preseismic Fault Creep and Elastic Wave Amplitude Precursors Scale With Lab Earthquake Magnitude for the Continuum of Tectonic Failure Modes

Controlling Anthropogenic and Natural Seismicity: Insights From Active Stabilization of the Spring‐Slider Model

Slow and fast ruptures on a laboratory fault controlled by loading characteristics

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