Analogue earthquakes and seismic cycles: experimental modelling across timescales

Rosenau, Matthias; Corbi, Fabio; Dominguez, Stéphane

doi:10.5194/se-8-597-2017

Cited by 57 publications

(48 citation statements)

References 239 publications

(346 reference statements)

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“…Basins are hypothetically a geologic indicator of asperities [Mogi, 1969;Nishenko and McCann, 1979;Wells et al, 2003;Fuller et al, 2006;Rosenau et al, 2017;Saillard et al, 2017], while high slip deficit rate zones highlight coupled locked areas of the megathrust where stress builds up during the monitoring period (i.e., the last 6 years in the case of Nankai).…”

Section: Nankai Benchmarkmentioning

confidence: 99%

“…Therefore, seismic waves are unlikely to be excited and dynamic effects not present. We adopted the "seismotectonic scale models" approach to develop our models, taking therefore into account geometric, kinematic, and dynamic similarity criteria [e.g., Hubbert, 1937;Rosenau et al, 2017]. An important consequence of such scaling is the introduction of a dyadic time-scaling factor that allows slowing down the earthquake rupture process and speeding up the interseismic stress buildup phase, keeping dynamic similarity in both stages Rosenau et al, 2017].…”

Section: 1002/2017gl074182mentioning

confidence: 99%

“…We adopted the "seismotectonic scale models" approach to develop our models, taking therefore into account geometric, kinematic, and dynamic similarity criteria [e.g., Hubbert, 1937;Rosenau et al, 2017]. An important consequence of such scaling is the introduction of a dyadic time-scaling factor that allows slowing down the earthquake rupture process and speeding up the interseismic stress buildup phase, keeping dynamic similarity in both stages Rosenau et al, 2017]. Despite the unavoidable experimental oversimplifications, the main advantages of analog models are: (a) the physically self-consistent behavior, which allows spontaneously nucleating analog earthquakes as a result of stress build-up and plates interface strength; (b) the capability of reproducing tens of seismic cycles in a convenient experimental time; and (c) the 3-D nature of the setup, which is mandatory for studying the synchronization process.…”

Section: 1002/2017gl074182mentioning

confidence: 99%

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Control of asperities size and spacing on seismic behavior of subduction megathrusts

Corbi

Funiciello

Brizzi

et al. 2017

Geophysical Research Letters

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The majority of the largest subduction megathrust earthquakes share the common characteristic of rupturing more than one asperity along strike of the margin. Understanding the factors that control coseismic failure of multiple asperities, and thus maximum magnitude, is central for seismic hazard assessment. To investigate the role of asperities size and spacing on maximum magnitude, seismicity rate, and percentage of synchronized ruptures, we use analog models simulating along‐strike rupture behavior of megathrust earthquakes. We found negative correlations between the barrier‐to‐asperity length ratio Db/Da and maximum magnitude and seismicity rate. Db/Da also controls the process of asperities synchronization along the megathrust. A permanent barrier behavior is observed for Db/Da > 0.5. Comparing our experimental results to the Nankai Trough historical seismicity, we propose that the distribution of megathrust frictional heterogeneities likely explains the diversity of earthquakes which occurred there.

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Section: Nankai Benchmarkmentioning

confidence: 99%

Section: 1002/2017gl074182mentioning

confidence: 99%

Section: 1002/2017gl074182mentioning

confidence: 99%

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Control of asperities size and spacing on seismic behavior of subduction megathrusts

Corbi

Funiciello

Brizzi

et al. 2017

Geophysical Research Letters

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“…Although the recurrence behavior of earthquakes on a single fault is quasiperiodic, under the assumption of constant loading rates and frictional parameters, it is not possible to predict the onset of seismic slip (Ben-Zion et al, 2003). Therefore, numerical simulations and physical experiments have been designed to model fault slip and the seismic cycle (Rosenau et al, 2017). Because of the multiscale nature of fault slip, many numerical simulations are limited to either short (e.g., rupture models) (Heinecke et al, 2014) or long timescales (e.g., geodynamic models) (Dinther et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Only few numerical techniques allow the combination of short term and long term processes, and frequently the parametrization and implementation of the non-linear, multiscale interactions between the long and short timescales remains difficult (Avouac, 2015). Seismotectonic analog experiments allow to address the multiscale nature of slip on a laboratory scale and may provide additional insight into the deformation over multiple seismic cycles (Rosenau et al, 2017). Even though the analog experiments are strong simplifications of a seismogenic fault system, they inherently show stick-slip dynamics without the need of a complex integration scheme (Caruso et al, 2007;Marković and Gros, 2014).…”

Section: Introductionmentioning

confidence: 99%

Smart Speed Imaging in Digital Image Correlation: Application to Seismotectonic Scale Modeling

et al. 2019

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Analog models of earthquakes and seismic cycles are characterized by strong variations in strain rate: from slow interseismic loading to fast coseismic release of elastic energy. Deformation rates vary accordingly from micrometer per second (e.g., plate tectonic motion) to meter per second (e.g., rupture propagation). Deformation values are very small over one seismic cycle, in the order of a few tens of micrometer, because of the scaled nature of such models. This cross-scale behavior poses a major challenge to effectively monitor the experiments by means of digital image correlation techniques, i.e., at high resolution (>100 Hz) during the coseismic period but without dramatically oversampling the interseismic period. We developed a smart speed imaging tool which allows on-the-fly scaling of imaging frequency with strain rate, based on an external trigger signal and a buffer. The external trigger signal comes from a force sensor that independently detects stress drops associated with analog earthquakes which triggers storage of a short high frequency image sequence from the buffer. After the event has passed, the system returns to a low speed mode in which image data is downsampled until the next event trigger. Here we introduce the concept of smart speed imaging and document the necessary hard-and software. We test the algorithms in generic and real applications. A new analog earthquake setup based on a modification of the Schulze ring-shear tester is used to verify the technique and discuss alternative trigger systems.

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Growing Faults in the Lab: Insights Into the Scale Dependence of the Fault Zone Evolution Process

2018

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Analog sandbox experiments are a widely used method to investigate tectonic processes that cannot be resolved from natural data alone, such as strain localization and the formation of fault zones. Despite this, it is still unclear to which extent the dynamics of strain localization and fault zone formation seen in sandbox experiments can be extrapolated to a natural prototype. Of paramount importance for dynamic similarity is the proper scaling of the work required to create the fault system, Wprop. Using analog sandbox experiments of strike‐slip deformation, we show Wprop to scale approximately with the square of the fault system length, l, which is consistent with the theory of fault growth in nature. Through quantitative measurements of both Wprop and strain distribution we are able to show that Wprop is mainly spent on diffuse deformation prior to localization, which we therefore regard as analogous to distributed deformation on small‐scale faults below seismic resolution in natural fault networks. Finally, we compare our data to estimates of the work consumed by natural fault zones to verify that analog sandbox experiments scale properly with respect to energy, that is, that they scale truly dynamically.

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Analogue earthquakes and seismic cycles: experimental modelling across timescales

Cited by 57 publications

References 239 publications

Control of asperities size and spacing on seismic behavior of subduction megathrusts

Control of asperities size and spacing on seismic behavior of subduction megathrusts

Smart Speed Imaging in Digital Image Correlation: Application to Seismotectonic Scale Modeling

Growing Faults in the Lab: Insights Into the Scale Dependence of the Fault Zone Evolution Process

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