Simulation of seismic waves at the earth's crust (brittle–ductile transition) based on the Burgers model

Carcione, José M.; Poletto, Flávio; Farina, Biancamaria; Craglietto, A.

doi:10.5194/se-5-1001-2014

Cited by 14 publications

(11 citation statements)

References 25 publications

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“…While stress‐dependence can lead to effective viscosity that changes in time, it is not the same as transient rheology in which the solid Earth response is dependent on the loading frequency. The (extended) Burgers rheology is a notable example of a rheology that includes transient creep (Ivins et al., 2020; Jackson & Faul, 2010), It is used for example for post‐seismic deformation (Nield et al., 2020) and seismic wave response (Carcione et al., 2014). It is possible that the response of the loading to ice load changes since is also governed by transient creep.…”

Section: Introductionmentioning

confidence: 99%

Effect of Lateral and Stress‐Dependent Viscosity Variations on GIA Induced Uplift Rates in the Amundsen Sea Embayment

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Barletta²,

et al. 2021

Geochem Geophys Geosyst

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Accurate GIA models are required for correcting measurements of mass change in Antarctica and for improving knowledge of the sub-surface, especially in areas of large current ice loss such as the Amundsen Sea Embayment(ASE). Regionally, seismic and gravity data suggests lateral differences in viscosity (3D). Furthermore, mantle flow laws allow for a stress-dependent effective viscosity which changes over time (3D-s). In this study we investigate whether models with 3D/3D-s have significant effects on the uplift in the region. We use a finite element model with composite rheology consisting of diffusion and dislocation creep, forced by an ice deglaciation model starting in 1900. We use its uplift predictions as synthetic observations to test the performance of 1D model inversion in the presence of viscosity variations. Stress-dependent rheology results in lower viscosity beneath the load and a more localized uplift pattern. We demonstrate that the background stress from earlier ice load changes can both increase or decrease the influence of stress-induced effective viscosity changes. For the ASE, fitting 1D models to 3D model uplift results in a best fitting model with viscosity that represents the average of a large area, while for 3D-s rheology, local viscosity is more influential. 1D models are statistically indistinguishable from 3D/3D-s viscosity with current GPS stations. However, 3D and 3D-

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Section: Introductionmentioning

confidence: 99%

Effect of Lateral and Stress‐Dependent Viscosity Variations on GIA Induced Uplift Rates in the Amundsen Sea Embayment

Blank

Barletta²,

et al. 2021

Geochem Geophys Geosyst

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“…Carcione and Poletto (2013) proposed an elasticplastic rheology to model the BDT based on the Burgers mechanical model, including the effects of anisotropy, seismic attenuation, and temperature by the Arrhenius equation. Carcione et al (2014) presented an algorithm to simulate full seismic wave propagation in heterogeneous media in the presence of the BDT, using the Burgers mechanical model and the Arrhenius equation to take into account viscoelastic behavior, temperature dependence, and rock melting conditions. Carcione et al (2016) extended the theory to include poro-viscoelastic media by explicitly modeling the effects of fluids under supercritical conditions.…”

Section: Conceptual Models and Numerical Simulation Studiesmentioning

confidence: 99%

Utilizing supercritical geothermal systems: a review of past ventures and ongoing research activities

Reinsch

Dobson

Asanuma³

et al. 2017

Geotherm Energy

153

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“…Linear viscoelastic models based on a Burgers model have been widely applied to a range of phenomena including glacial isostatic adjustment (Yuen et al 1986;e.g., Rumpker andWolff 1996), postseismic creep (e.g., Hetland andHager 2005;Pollitz, Bürgmann, and Banerjee 2006), tidal dissipation (e.g., Nimmo, Faul, and Garnero 2012;Nimmo and Faul 2013;Bierson and Nimmo 2016), and seismic attenuation (Carcione et al 2014;S.-I. Karato 2012).…”

Section: Consequences For Transient Creep In the Upper Mantlementioning

confidence: 99%

Dislocation creep of olivine: Backstress evolution controls transient creep at high temperatures

Hansen

Wallis

Breithaupt

et al. 2021

Preprint

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Transient creep occurs during geodynamic processes that impose stress changes on rocks at high temperatures. The transient is manifested as evolution in the viscosity of the rocks until steady-state flow is achieved. Although several phenomenological models of transient creep in rocks have been proposed, the dominant microphysical processes that control such behavior remain poorly constrained. To identify the intragranular processes that contribute to transient creep of olivine, we performed stress-reduction Preprint submitted to ESSOAr and Journal of Geophysical Research -Solid Earth 2 tests on single crystals of olivine at temperatures of 1250-1300°C. In these experiments, samples undergo time-dependent reverse strain after the stress reduction. The magnitude of reverse strain is ~10 -3 and increases with increasing magnitude of the stress reduction. High-angular resolution electron backscatter diffraction analyses of deformed material reveal lattice curvature and heterogeneous stresses associated with the dominant slip system. The mechanical and microstructural data are consistent with transient creep of the single crystals arising from accumulation and release of backstresses among dislocations. These results allow the dislocation-glide component of creep at high temperatures to be isolated, and we use these data to calibrate a flow law for olivine to describe the glide component of creep over a wide temperature range. We argue that this flow law can be used to estimate both transient creep and steadystate viscosities of olivine, with the transient evolution controlled by the evolution of the backstress. This model is able to predict variability in the style of transient (normal versus inverse) and the load-relaxation response observed in previous work.c Cooper et al. Hanson and Spetzler This study Normal Inverse

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Simulation of seismic waves at the earth's crust (brittle–ductile transition) based on the Burgers model

Cited by 14 publications

References 25 publications

Effect of Lateral and Stress‐Dependent Viscosity Variations on GIA Induced Uplift Rates in the Amundsen Sea Embayment

Effect of Lateral and Stress‐Dependent Viscosity Variations on GIA Induced Uplift Rates in the Amundsen Sea Embayment

Utilizing supercritical geothermal systems: a review of past ventures and ongoing research activities

Dislocation creep of olivine: Backstress evolution controls transient creep at high temperatures

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