Volume-Based Modelling of Fault Reactivation in Porous Media Using a Visco-Elastic Proxy Model

Beck, Martin; Seitz, Gabriele; Class, Holger

doi:10.1007/s11242-016-0663-5

Cited by 12 publications

(9 citation statements)

References 38 publications

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“…The developed preconditioner exhibits good scalability properties for challenging problems regardless of dominant physics. Beck et al (2016) present a conceptual approach to model fault reactivation in porous media. They interpret failure as a dissipation of elastic energy and thus replace the originally linear elastic material law by a visco-elastic law.…”

Section: Research Area B: Numerical Methodsmentioning

confidence: 99%

Editorial

et al. 2016

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This special issue of Transport in Porous Media contains contributions from the community of researchers within the NUPUS collaboration. Submissions are authored by the full range of NUPUS members, from senior faculty members to the young researchers whose studies have been shaped by this international training network. Many of the contributions highlight the strong inter-university, inter-disciplinary and international connections which are reviewed in the accompanying foreword . The topics of this special issue reflect those of NUPUS itself, and the contributions are grouped in the NUPUS research areas as follows.

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Section: Research Area B: Numerical Methodsmentioning

confidence: 99%

Editorial

et al. 2016

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“…The energies, into which the elastic energy is transformed, are not considered since they are either dissipated or negligible for the stress redistribution. There are other recently introduced approaches (Berge et al, 2017;Ucar et al, 2018;Gómez Castro et al, 2017) that calculate the stress drop required for reaching the equilibrium, which is in fact the excess shear stress. Our approach uses a constant value, and therefore ends up either beyond the equilibrium or does not yet reach it, the latter case would trigger immediately another failure event.…”

Section: Modelling Conceptmentioning

confidence: 99%

Modelling fault reactivation with characteristic stress-drop terms

Beck

Class

2019

Adv. Geosci.

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Abstract. Predicting shear failure that leads to the reactivation of faults during the injection of fluids in the subsurface is difficult since it inherently involves an enormous complexity of flow processes interacting with geomechanics. However, understanding and predicting induced seismicity is of great importance. Various approaches to modelling shear failure have been suggested recently. They are all dependent on the prediction of the pressure and stress field, which requires the solution of partial differential equations for flow and for geomechanics. Given a pressure and corresponding mechanical responses, shear slip can be detected using a failure criterion. We propose using characteristic values for stress drops occurring in a failure event as sinks in the geomechanical equation. This approach is discussed in this article and illustrated with an example.

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“…Poroelastic coupling plays a major role in the presence of faults and fractures (Rutqvist et al, ; Rutqvist & Stephansson, ; Segura & Carol, ). Faults are typically represented either as 3‐D failure zones with slip‐weakening rheology (Beck et al, ; Borja, ; Rutqvist et al, ), or as frictional contact surfaces (Ferronato et al, ; Ghassemi & Tao, ; Jha & Juanes, ; Morris, Hao, et al, ). The latter approach, adopted in this study, is consistent with the observed structure of mature faults, which suggests that shearing during earthquake slip events localizes within a thin granular core (Rice, ).…”

Section: Mathematical Model: Poroelasticity and Fault Frictional Behamentioning

confidence: 99%

“…Measures of tendency to slip, mobilized friction angle, Coulomb failure analysis (Reasenberg & Simpson, ), and estimates of coseismic fault slip based on simplified fault rheologies have proven very useful to understand the geomechanical challenges posed by subsurface energy technologies. Thermohydromechanical models of induced seismicity have focused on fault reactivation through estimates of tendency to slip (De Simone et al, ; Jacquey et al, ; Kim & Hosseini, ; Li & Laloui, ; Morris, Detwiler, et al, ; Rutqvist et al, ; Vidal‐Gilbert et al, ; Vilarrasa et al, ; Vilarrasa et al, ), estimates of coseismic slip from slip‐weakening friction laws (Beck et al, ; Cappa & Rutqvist, , ; Jeanne et al, ; Jha & Juanes, ; Morris, Hao, et al, ; Rinaldi et al, ; Rohmer, ; Taron & Elsworth, ), or connecting poroelastic stressing to models of earthquake production rate (Chang & Segall, , ; Dieterich, ; Segall & Lu, ). Over the past decade, there have been numerous contributions to hydromechanical modeling of induced seismicity, often combining two separate codes to sequentially solve for fluid flow and rock mechanics (Cappa & Rutqvist, , ; Jha & Juanes, ; Rutqvist et al, ).…”

Section: Introductionmentioning

confidence: 99%

Numerical Modeling of Injection‐Induced Earthquakes Using Laboratory‐Derived Friction Laws

Cueto‐Felgueroso

Vila

Santillán

et al. 2018

Water Resources Research

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Modeling injection-induced earthquakes requires coupling porous media flow, rock mechanics, and fault friction. Highly nonlinear laboratory-derived constitutive laws for fault friction pose a major challenge for computational models that couple flow and geomechanics. We present a finite element formulation to simulate injection-induced earthquake sequences in rate-and-state faults embedded in poroelastic media. We simulate all phases of the stick-slip cycle: from fault reactivation as pressure accumulates near the fault, to earthquake nucleation phase, coseismic rupture propagation and interseismic periods. Our simulations are quasi-dynamic: we neglect inertia, and adopt the so-called radiation damping approximation. We perform validation and verification tests based on a simple spring-block analog that allows straightforward comparison between our 2-D finite element model and the single-degree-of-freedom dynamics. We also verify our frictional contact algorithm by simulating injection-induced earthquakes on a slip-weakening strike-slip fault. We finally study the impact of different rate-and-state laws (aging and slip laws), as well as the role of the degree of poroelastic coupling, by varying the Biot coefficient. We characterize the undrained pressure response triggered by the fast propagation of rupture fronts. Undrained pressure changes during rupture act as an additional coseismic weakening mechanism, controlling the propagation or arrest of the rupture fronts. We find that this feedback between pore pressure and slip propagation, which is absent in uncoupled simulations, leads to distinctively asymmetric rupture patterns in induced earthquakes in poroelastic media. Our results show that capturing the coupling between fault frictional processes and rock poroelastic behavior requires well-resolved and fully coupled simulations.A recent increase in seismicity rates has drawn attention toward injection-induced earthquakes and their potentially

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Volume-Based Modelling of Fault Reactivation in Porous Media Using a Visco-Elastic Proxy Model

Cited by 12 publications

References 38 publications

Editorial

Editorial

Modelling fault reactivation with characteristic stress-drop terms

Numerical Modeling of Injection‐Induced Earthquakes Using Laboratory‐Derived Friction Laws

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