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1. Incorporating Full Elastodynamic Effects and Dipping Fault Geometries in Community Code Verification Exercises for Simulations of Earthquake Sequences and Aseismic Slip (SEAS)

Author

Erickson, Brittany A, Jiang, Junle, Lambert, Valère, Barbot, Sylvain D, Abdelmeguid, Mohamed, Almquist, Martin, Ampuero, Jean-Paul, Ando, Ryosuke, Cattania, Camilla, Chen, Alexandre, Dal Zilio, Luca, Deng, Shuai, Dunham, Eric M, Elbanna, Ahmed E, Gabriel, Alice-Agnes, Harvey, Tobias W, Huang, Yihe, Kaneko, Yoshihiro, Kozdon, Jeremy E, Lapusta, Nadia, Li, Duo, Li, Meng, Liang, Chao, Liu, Yajing, Ozawa, So, Perez-Silva, Andrea, Pranger, Casper, Segall, Paul, Sun, Yudong, Thakur, Prithvi, Uphoff, Carsten, van Dinther, Ylona, and Yang, Yuyun

Subjects
Earth Sciences, Engineering, Geophysics, Civil Engineering, Geochemistry & Geophysics, Civil engineering
Abstract

ABSTRACT: Numerical modeling of earthquake dynamics and derived insight for seismic hazard relies on credible, reproducible model results. The sequences of earthquakes and aseismic slip (SEAS) initiative has set out to facilitate community code comparisons, and verify and advance the next generation of physics-based earthquake models that reproduce all phases of the seismic cycle. With the goal of advancing SEAS models to robustly incorporate physical and geometrical complexities, here we present code comparison results from two new benchmark problems: BP1-FD considers full elastodynamic effects, and BP3-QD considers dipping fault geometries. Seven and eight modeling groups participated in BP1-FD and BP3-QD, respectively, allowing us to explore these physical ingredients across multiple codes and better understand associated numerical considerations. With new comparison metrics, we find that numerical resolution and computational domain size are critical parameters to obtain matching results. Codes for BP1-FD implement different criteria for switching between quasi-static and dynamic solvers, which require tuning to obtain matching results. In BP3-QD, proper remote boundary conditions consistent with specified rigid body translation are required to obtain matching surface displacements. With these numerical and mathematical issues resolved, we obtain excellent quantitative agreements among codes in earthquake interevent times, event moments, and coseismic slip, with reasonable agreements made in peak slip rates and rupture arrival time. We find that including full inertial effects generates events with larger slip rates and rupture speeds compared to the quasi-dynamic counterpart. For BP3-QD, both dip angle and sense of motion (thrust versus normal faulting) alter ground motion on the hanging and foot walls, and influence event patterns, with some sequences exhibiting similar-size characteristic earthquakes, and others exhibiting different-size events. These findings underscore the importance of considering full elastodynamics and nonvertical dip angles in SEAS models, as both influence short- and long-term earthquake behavior and are relevant to seismic hazard.

Published
2023

3. Estimating geodynamic model parameters from geodetic observations using a particle method

Author

Marsman, Celine, Vossepoel, Femke, van Dinther, Ylona, Govers, Rob, Marsman, Celine, Vossepoel, Femke, van Dinther, Ylona, and Govers, Rob

Abstract

Bayesian-based data assimilation methods integrate observational data into geophysical forward models to obtain the temporal evolution of an improved state vector, including its uncertainties. We explore the potential of a variant, a particle method, to estimate mechanical parameters of the overriding plate during the interseismic period. Here we assimilate vertical surface displacements into an elementary flexural model to estimate the elastic thickness of the overriding plate, and the locations and magnitudes of line loads acting on the overriding plate to produce flexure. Assimilation of synthetic observations sampled from a different forward model than is used in the particle method, reveal that synthetic seafloor data within 150 km from the trench are required to properly constrain parameters for long wavelength solutions of the upper plate (i.e. wavelength ∼500 km). Assimilation of synthetic observations sampled from the same flexural model used in the particle method shows remarkable convergence towards the true parameters with synthetic on-land data only for short to intermediate wavelength solutions (i.e. wavelengths between ∼100 and 300 km). In real-data assimilation experiments we assign representation errors due to discrepancies between our incorrect or incomplete physical model and the data. When assimilating continental data prior to the 2011 Mw Tohoku-Oki earthquake (1997–2000), an unrealistically low effective elastic plate thickness for Tohoku of ∼5–7 km is estimated. Our synthetic experiments suggest that improvements to the physical forward model, such as the inclusion of a slab, a megathrust interface and viscoelasticity of the mantle, including accurate seafloor data, and additional geodetic observations, may refine our estimates of the effective elastic plate thickness. Overall, we demonstrate the potential of using the particle method to constrain geodynamic parameters by providing constraints on parameters and corresponding uncertainty values

Published
2024

6. Viscoelastic Crustal Deformation Computation Method with Reduced Random Memory Accesses for GPU-Based Computers

Author

Yamaguchi, Takuma, Fujita, Kohei, Ichimura, Tsuyoshi, Glerum, Anne, van Dinther, Ylona, Hori, Takane, Schenk, Olaf, Hori, Muneo, Wijerathne, Lalith, Hutchison, David, Series Editor, Kanade, Takeo, Series Editor, Kittler, Josef, Series Editor, Kleinberg, Jon M., Series Editor, Mattern, Friedemann, Series Editor, Mitchell, John C., Series Editor, Naor, Moni, Series Editor, Pandu Rangan, C., Series Editor, Steffen, Bernhard, Series Editor, Terzopoulos, Demetri, Series Editor, Tygar, Doug, Series Editor, Weikum, Gerhard, Series Editor, Shi, Yong, editor, Fu, Haohuan, editor, Tian, Yingjie, editor, Krzhizhanovskaya, Valeria V., editor, Lees, Michael Harold, editor, Dongarra, Jack, editor, and Sloot, Peter M. A., editor

Published
2018
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10. A comparative analysis of continuum plasticity, viscoplasticity and phase-field models for earthquake sequence modeling

Author

Goudarzi, Mohsen, Gerya, Taras, van Dinther, Ylona, Goudarzi, Mohsen, Gerya, Taras, and van Dinther, Ylona

Abstract

This paper discusses continuum models for simulating earthquake sequences on faults governed by rate-and-state dependent friction. Through detailed numerical analysis of a conventional strike-slip fault, new observations regarding the use of various continuum earthquake models are presented. We update a recently proposed plasticity-based model using a consistently linearized formulation, show its agreement with discrete fault models for fault thicknesses of hundreds of meters, and demonstrate mesh objectivity for slip-related variables. To obtain a fully regularized fault width description with an internal length scale, we study the performance and mesh convergence of a plasticity-based model complemented by a Kelvin viscosity term and the phase-field approach to cohesive fracture. The Kelvin viscoplasticity-based model can introduce an internal length scale and a mesh-objective response. However, on grid sizes down to meters, this only holds for very high Kelvin viscosities that inhibit seismic slip rates, which renders this approach impractical for simulating earthquake sequences. On the other hand, our phase-field implementation for earthquake sequences provides a numerically robust framework that agrees with a discrete reference solution, is mesh objective, and reaches seismic slip rates. The model, unsurprisingly, requires highly refined grids around the fault zones to reproduce results close to a discrete model. Following this line, the effect of an internal length scale parameter on the phase-field predictions and mesh convergence are discussed.

Published
2023

11. Incorporating Full Elastodynamic Effects and Dipping Fault Geometries in Community Code Verification Exercises for Simulations of Earthquake Sequences and Aseismic Slip (SEAS)

Author

Erickson, Brittany A., Jiang, Junle, Lambert, Valère, Barbot, Sylvain D., Abdelmeguid, Mohamed, Almquist, Martin, Ampuero, Jean‐Paul, Ando, Ryosuke, Cattania, Camilla, Chen, Alexandre, Dal Zilio, Luca, Deng, Shuai, Dunham, Eric M., Elbanna, Ahmed E., Gabriel, Alice‐Agnes, Harvey, Tobias W., Huang, Yihe, Kaneko, Yoshihiro, Kozdon, Jeremy E., Lapusta, Nadia, Li, Duo, Li, Meng, Liang, Chao, Liu, Yajing, Ozawa, So, Perez‐Silva, Andrea, Pranger, Casper, Segall, Paul, Sun, Yudong, Thakur, Prithvi, Uphoff, Carsten, van Dinther, Ylona, Yang, Yuyun, Erickson, Brittany A., Jiang, Junle, Lambert, Valère, Barbot, Sylvain D., Abdelmeguid, Mohamed, Almquist, Martin, Ampuero, Jean‐Paul, Ando, Ryosuke, Cattania, Camilla, Chen, Alexandre, Dal Zilio, Luca, Deng, Shuai, Dunham, Eric M., Elbanna, Ahmed E., Gabriel, Alice‐Agnes, Harvey, Tobias W., Huang, Yihe, Kaneko, Yoshihiro, Kozdon, Jeremy E., Lapusta, Nadia, Li, Duo, Li, Meng, Liang, Chao, Liu, Yajing, Ozawa, So, Perez‐Silva, Andrea, Pranger, Casper, Segall, Paul, Sun, Yudong, Thakur, Prithvi, Uphoff, Carsten, van Dinther, Ylona, and Yang, Yuyun

Abstract

Numerical modeling of earthquake dynamics and derived insight for seismic hazard relies on credible, reproducible model results. The sequences of earthquakes and aseismic slip (SEAS) initiative has set out to facilitate community code comparisons, and verify and advance the next generation of physics‐based earthquake models that reproduce all phases of the seismic cycle. With the goal of advancing SEAS models to robustly incorporate physical and geometrical complexities, here we present code comparison results from two new benchmark problems: BP1‐FD considers full elastodynamic effects, and BP3‐QD considers dipping fault geometries. Seven and eight modeling groups participated in BP1‐FD and BP3‐QD, respectively, allowing us to explore these physical ingredients across multiple codes and better understand associated numerical considerations. With new comparison metrics, we find that numerical resolution and computational domain size are critical parameters to obtain matching results. Codes for BP1‐FD implement different criteria for switching between quasi‐static and dynamic solvers, which require tuning to obtain matching results. In BP3‐QD, proper remote boundary conditions consistent with specified rigid body translation are required to obtain matching surface displacements. With these numerical and mathematical issues resolved, we obtain excellent quantitative agreements among codes in earthquake interevent times, event moments, and coseismic slip, with reasonable agreements made in peak slip rates and rupture arrival time. We find that including full inertial effects generates events with larger slip rates and rupture speeds compared to the quasi‐dynamic counterpart. For BP3‐QD, both dip angle and sense of motion (thrust versus normal faulting) alter ground motion on the hanging and foot walls, and influence event patterns, with some sequences exhibiting similar‐size characteristic earthquakes, and others exhibiting different‐size events. These findings undersco

Published
2023

12. Incorporating Full Elastodynamic Effects and Dipping Fault Geometries in Community Code Verification Exercises for Simulations of Earthquake Sequences and Aseismic Slip (SEAS)

Author

Tectonics, Erickson, Brittany A., Jiang, Junle, Lambert, Valère, Barbot, Sylvain D., Abdelmeguid, Mohamed, Almquist, Martin, Ampuero, Jean‐Paul, Ando, Ryosuke, Cattania, Camilla, Chen, Alexandre, Dal Zilio, Luca, Deng, Shuai, Dunham, Eric M., Elbanna, Ahmed E., Gabriel, Alice‐Agnes, Harvey, Tobias W., Huang, Yihe, Kaneko, Yoshihiro, Kozdon, Jeremy E., Lapusta, Nadia, Li, Duo, Li, Meng, Liang, Chao, Liu, Yajing, Ozawa, So, Perez‐Silva, Andrea, Pranger, Casper, Segall, Paul, Sun, Yudong, Thakur, Prithvi, Uphoff, Carsten, van Dinther, Ylona, Yang, Yuyun, Tectonics, Erickson, Brittany A., Jiang, Junle, Lambert, Valère, Barbot, Sylvain D., Abdelmeguid, Mohamed, Almquist, Martin, Ampuero, Jean‐Paul, Ando, Ryosuke, Cattania, Camilla, Chen, Alexandre, Dal Zilio, Luca, Deng, Shuai, Dunham, Eric M., Elbanna, Ahmed E., Gabriel, Alice‐Agnes, Harvey, Tobias W., Huang, Yihe, Kaneko, Yoshihiro, Kozdon, Jeremy E., Lapusta, Nadia, Li, Duo, Li, Meng, Liang, Chao, Liu, Yajing, Ozawa, So, Perez‐Silva, Andrea, Pranger, Casper, Segall, Paul, Sun, Yudong, Thakur, Prithvi, Uphoff, Carsten, van Dinther, Ylona, and Yang, Yuyun

Published
2023

16. Community‐Driven Code Comparisons for Three‐Dimensional Dynamic Modeling of Sequences of Earthquakes and Aseismic Slip

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Jiang, Junle, Erickson, Brittany A, Lambert, Valère R, Ampuero, Jean-Paul, Ando, Ryosuke, Barbot, Sylvain D, Cattania, Camilla, Zilio, Luca Dal, Duan, Benchun, Dunham, Eric M, Gabriel, Alice-Agnes, Lapusta, Nadia, Li, Duo, Li, Meng, Liu, Dunyu, Liu, Yajing, Ozawa, So, Pranger, Casper, van Dinther, Ylona, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Jiang, Junle, Erickson, Brittany A, Lambert, Valère R, Ampuero, Jean-Paul, Ando, Ryosuke, Barbot, Sylvain D, Cattania, Camilla, Zilio, Luca Dal, Duan, Benchun, Dunham, Eric M, Gabriel, Alice-Agnes, Lapusta, Nadia, Li, Duo, Li, Meng, Liu, Dunyu, Liu, Yajing, Ozawa, So, Pranger, Casper, and van Dinther, Ylona

Published
2023

20. Quantifying continental collision dynamics for Alpine-style orogens

Author

van Agtmaal, Luuk, van Dinther, Ylona, Willingshofer, Ernst, Matenco, Liviu, and Tectonics

Subjects
continental collision, force quantification, numerical modelling, Earth and Planetary Sciences(all), dynamic models, slab pull, subduction, mantle drag
Abstract

When continents collide, the arrival of positively buoyant continental crust slows down subduction. This collision often leads to the detachment of earlier subducted oceanic lithosphere, which changes the subsequent dynamics of the orogenic system. Recent studies of continental collision infer that the remaining slab may drive convergence through slab roll-back even after detachment. Here we use two-dimensional visco-elasto-plastic thermo-mechanical models to explore the conditions for post-collisional slab steepening versus shallowing by quantifying the dynamics of continental collision for a wide range of parameters. We monitor the evolution of horizontal mantle drag beneath the overriding plate and vertical slab pull to show that these forces have similar magnitudes and interact continuously with each other. We do not observe slab rollback or steepening after slab detachment within our investigated parameter space. Instead, we observe a two-stage elastic and viscous slab rebound process lasting tens of millions of years, which is associated with slab unbending and eduction that together generate orogenic widening and trench shift towards the foreland. Our parametric studies show that the initial length of the oceanic plate and the stratified lithospheric rheology exert a key control on the orogenic evolution. When correlated with previous studies our results suggest that post-detachment slab rollback may only be possible when minor amounts of continental crust subduct. Among the wide variety of natural scenarios, our modelling applies best to the evolution of the Central European Alps. Furthermore, the mantle drag force may play a more important role in continental dynamics than previously thought. Finally, our study illustrates that dynamic analysis is a useful quantitative framework that also intuitively explains observed model kinematics.

Published
2022

27. Incorporating Full Elastodynamic Effects and Dipping Fault Geometries in Community Code Verification Exercises for Simulations of Earthquake Sequences and Aseismic Slip (SEAS)

Author

Erickson, Brittany, Jiang, Junle, Lambert, Valere, Abdelmeguid, Mohamed, Almquist, Martin, Ampuero, Jean Paul, Ando, Ryosuke, Barbot, Sylvain, Cattania, Camilla, Chen, Alexandre, Dal Zilio, Luca, Dunham, Eric, Elbanna, Ahmed, Gabriel, Alice-Agnes, Harvey, Tobias, Huang, Yihe, Kaneko, Yoshihiro, Kozdon, Jeremy, Lapusta, Nadia, Li, Duo, Li, Meng, Liang, Chao, Liu, Yajing, Ozawa, So, Pranger, Casper, Segall, Paul, Sun, Yudong, Thakur, Prithvi, Uphoff, Carsten, van Dinther, Ylona, Yang, Yuyun, Erickson, Brittany, Jiang, Junle, Lambert, Valere, Abdelmeguid, Mohamed, Almquist, Martin, Ampuero, Jean Paul, Ando, Ryosuke, Barbot, Sylvain, Cattania, Camilla, Chen, Alexandre, Dal Zilio, Luca, Dunham, Eric, Elbanna, Ahmed, Gabriel, Alice-Agnes, Harvey, Tobias, Huang, Yihe, Kaneko, Yoshihiro, Kozdon, Jeremy, Lapusta, Nadia, Li, Duo, Li, Meng, Liang, Chao, Liu, Yajing, Ozawa, So, Pranger, Casper, Segall, Paul, Sun, Yudong, Thakur, Prithvi, Uphoff, Carsten, van Dinther, Ylona, and Yang, Yuyun

Abstract

eSSENCE - An eScience Collaboration

Published
2022
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29. On parameter bias in earthquake sequence models using data assimilation.

Author

Banerjee, Arundhuti, van Dinther, Ylona, and Vossepoel, Femke C.

Subjects
KALMAN filtering, SHEARING force, STRAINS & stresses (Mechanics), EARTHQUAKE prediction, PARAMETER estimation, DATA modeling, EARTHQUAKES
Abstract

The feasibility of physics-based forecasting of earthquakes depends on how well models can be calibrated to represent earthquake scenarios given uncertainties in both models and data. We investigate whether data assimilation can estimate current and future fault states, i.e., slip rate and shear stress, in the presence of a bias in the friction parameter. We perform state estimation as well as combined state-parameter estimation using a sequential-importance resampling particle filter in a zero-dimensional (0D) generalization of the Burridge–Knopoff spring–block model with rate-and-state friction. Minor changes in the friction parameter ϵ can lead to different state trajectories and earthquake characteristics. The performance of data assimilation with respect to estimating the fault state in the presence of a parameter bias in ϵ depends on the magnitude of the bias. A small parameter bias in ϵ (+3 %) can be compensated for very well using state estimation (R2 = 0.99), whereas an intermediate bias (- 14 %) can only be partly compensated for using state estimation (R2 = 0.47). When increasing particle spread by accounting for model error and an additional resampling step, R2 increases to 0.61. However, when there is a large bias (- 43 %) in ϵ , only state-parameter estimation can fully account for the parameter bias (R2 = 0.97). Thus, simultaneous state and parameter estimation effectively separates the error contributions from friction and shear stress to correctly estimate the current and future shear stress and slip rate. This illustrates the potential of data assimilation for the estimation of earthquake sequences and provides insight into its application in other nonlinear processes with uncertain parameters. [ABSTRACT FROM AUTHOR]

Published
2023
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30. Incorporating Full Elastodynamic Effects and Dipping Fault Geometries in Community Code Verification Exercises for Simulations of Earthquake Sequences and Aseismic Slip (SEAS)

Author

Erickson, Brittany, primary, Jiang, Junle, additional, Lambert, Valere, additional, Abdelmeguid, Mohamed, additional, Almquist, Martin, additional, Ampuero, Jean Paul, additional, Ando, Ryosuke, additional, Barbot, Sylvain, additional, Cattania, Camilla, additional, Chen, Alexandre, additional, Dal Zilio, Luca, additional, Dunham, Eric, additional, Elbanna, Ahmed, additional, Gabriel, Alice-Agnes, additional, Harvey, Tobias, additional, Huang, Yihe, additional, Kaneko, Yoshihiro, additional, Kozdon, Jeremy, additional, Lapusta, Nadia, additional, Li, Duo, additional, Li, Meng, additional, Liang, Chao, additional, Liu, Yajing, additional, Ozawa, So, additional, Pranger, Casper, additional, Segall, Paul, additional, Sun, Yudong, additional, Thakur, Prithvi, additional, Uphoff, Carsten, additional, van Dinther, Ylona, additional, and Yang, Yuyun, additional

Published
2022
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37. Community‐Driven Code Comparisons for Three‐Dimensional Dynamic Modeling of Sequences of Earthquakes and Aseismic Slip

Author

Jiang, Junle, primary, Erickson, Brittany A., additional, Lambert, Valère R., additional, Ampuero, Jean‐Paul, additional, Ando, Ryosuke, additional, Barbot, Sylvain D., additional, Cattania, Camilla, additional, Zilio, Luca Dal, additional, Duan, Benchun, additional, Dunham, Eric M., additional, Gabriel, Alice‐Agnes, additional, Lapusta, Nadia, additional, Li, Duo, additional, Li, Meng, additional, Liu, Dunyu, additional, Liu, Yajing, additional, Ozawa, So, additional, Pranger, Casper, additional, and van Dinther, Ylona, additional

Published
2022
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38. Community-Driven Code Comparisons for Three-Dimensional Dynamic Modeling of Sequences of Earthquakes and Aseismic Slip (SEAS)

Author

Jiang, Junle, primary, Erickson, Brittany, additional, Lambert, Valere, additional, Ampuero, Jean-Paul, additional, Ando, Ryosuke, additional, Barbot, Sylvain, additional, Cattania, Camilla, additional, Dal Zilio, Luca, additional, Duan, Benchun, additional, Dunham, Eric M, additional, Gabriel, Alice-Agnes, additional, Lapusta, Nadia, additional, Li, Duo, additional, Li, Meng, additional, Liu, Dunyu, additional, Liu, Yajing, additional, Ozawa, So, additional, Pranger, Casper, additional, and van Dinther, Ylona, additional

Published
2022
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41. Community-Driven Code Comparisons for Three-Dimensional Dynamic Modeling of Sequences of Earthquakes and Aseismic Slip (SEAS)

Author

Jiang, Junle, primary, Erickson, Brittany, additional, Lambert, Valere, additional, Ampuero, Jean-Paul, additional, Ando, Ryosuke, additional, Barbot, Sylvain, additional, Cattania, Camilla, additional, Dal Zilio, Luca, additional, Duan, Benchun, additional, Dunham, Eric M, additional, Gabriel, Alice-Agnes, additional, Lapusta, Nadia, additional, Li, Duo, additional, Li, Meng, additional, Liu, Dunyu, additional, Liu, Yajing, additional, Ozawa, So, additional, Pranger, Casper, additional, and van Dinther, Ylona, additional

Published
2021
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42. A regularized continuum model for fault zones with rate and state friction

Author

Mohsen Goudarzi, Taras Gerya, van Dinther Ylona, René de Borst, and Meng Li

Subjects
Continuum (topology), Geometry, State (functional analysis), Geology
Abstract

Accurate representation of fault zones is important in many applications in Earth sciences, including natural and induced seismicity. The framework developed here can efficiently model fault zone localization, evolution, and spontaneous fully dynamic earthquake sequences in a continuum plasticity framework. The geometrical features of the faults are incorporated into a regularized continuum framework, while the response of the fault zone is governed by a rate and state-dependent friction. Although a continuum plasticity model is advantageous to discrete approaches in representing evolving, unknown, or arbitrarily positioned faults, it is known that either non-associated plasticity or strain-softening can lead to mesh sensitivity of the numerical results in absence of an internal length scale. A common way to regularize the numerical model and introduce an internal length scale is by the adoption of a Kelvin-type visco-plasticity element. The visco-plastic rheological behavior for the bulk material is implemented along with a return-mapping algorithm for accurate stress and strain evolution. High slip rates (in the order of 1 m/s) are captured through numerical examples of a predefined strike-slip fault zone, where a detailed comparison with a reference discrete fault model is presented. Additionally, the regularization effect of the Kelvin viscosity parameter is studied on the fault slip velocity for a growing fault zone due to an initial material imperfection. The model is consistently linearized leading to quadratic convergence of the Newton solver. Although the proposed framework is a step towards the modeling of earthquake sequences for induced seismicity applications, the numerical model is general and can be applied to all tectonic settings including subduction zones.

Published
2021

43. On Parameter Bias in Earthquake Sequence Models using Data Assimilation.

Author

Banerjee, Arundhuti, van Dinther, Ylona, and Vossepoel, Femke C.

Subjects
SHEARING force, STRAINS & stresses (Mechanics), EARTHQUAKE prediction, KALMAN filtering, PARAMETER estimation, DATA modeling, EARTHQUAKES
Abstract

The feasibility of physics-based forecasting of earthquakes depends on how well models can be calibrated to represent earthquake scenarios given uncertainties in both models and data. We investigate whether data assimilation can estimate current and future fault states, i.e., slip rate and shear stress, in the presence of a bias in the friction parameter. We perform state estimation as well as combined state-parameter estimation using a sequential importance resampling particle filter in a 0D generalization of the Burridge-Knopoff spring-block model with rate-and-state friction. Minor changes in the friction parameter ϵ can lead to different state trajectories and earthquake characteristics. The performance of data assimilation in estimating the fault state in the presence of a parameter bias in ϵ depends on the magnitude of the bias. A small parameter bias in ϵ (+3 %) can be compensated very well using state estimation (R² = 0.99), whereas an intermediate bias (-14 %) can only be compensated partly (R² = 0.47). When increasing particle spread by accounting for model error and an additional resampling step R² increases to 0.61. However, when there is a large bias (-43 %) in ϵ, only state-parameter estimation can fully account for the parameter bias (R² = 0.97). Simultaneous state- and parameter estimation thus effectively separates error contributions from friction and shear stress to correctly estimate current and future shear stress and slip rate. This illustrates the potential of data assimilation for estimation of earthquake sequences and provides insight into its application in other non-linear processes with uncertain parameters. [ABSTRACT FROM AUTHOR]

Published
2022
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