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38 results on '"Cattania, Camilla"'

1. The role of gouge production in the seismic behavior of rough faults: A numerical study

Author

Castellano, Miguel, Milanese, Enrico, Cattania, Camilla, and Kammer, David S.

Subjects
Physics - Geophysics
Abstract

Fault zones mature through the accumulation of earthquakes and the wearing of contact asperities at multiple scales. This study examines how wear-induced gouge production affects the evolution of fault seismicity, focusing on earthquake nucleation, recurrence, and moment partitioning. Using 2D quasi-dynamic simulations integrating rate-and-state friction with Archard's law of wear, we model the space-time distribution of gouge and its effect on the critical slip distance. The study reveals a shift from single to multi-rupture nucleation, marked by increased foreshock activity. The recurrence interval undergoes two separate phases: an initial phase of steady increase followed by a secondary phase of unpredictable behavior. Finally, we observe a transition in the moment partitioning from faster to slower slip rates and a decrease in the moment released per cycle relative to the case where no gouge formation is simulated. This research sheds light on wear-driven mechanisms affecting fault slip behavior, offering valuable insights into how the evolution of gouge along a fault affects its seismic potential.

Published
2024

2. Energy dissipation in earthquakes

Author

Kammer, David S., McLaskey, Gregory C., Abercrombie, Rachel E., Ampuero, Jean-Paul, Cattania, Camilla, Cocco, Massimo, Zilio, Luca Dal, Dresen, Georg, Gabriel, Alice-Agnes, Ke, Chun-Yu, Marone, Chris, Selvadurai, Paul A., and Tinti, Elisa

Subjects
Physics - Geophysics
Abstract

Earthquakes are rupture-like processes that propagate along tectonic faults and cause seismic waves. The propagation speed and final area of the rupture, which determine an earthquake's potential impact, are directly related to the nature and quantity of the energy dissipation involved in the rupture process. Here we present the challenges associated with defining and measuring the energy dissipation in laboratory and natural earthquakes across many scales. We discuss the importance and implications of distinguishing between energy dissipation that occurs close to and far behind the rupture tip and we identify open scientific questions related to a consistent modeling framework for earthquake physics that extends beyond classical Linear Elastic Fracture Mechanics., Comment: 8 pages, 2 figures

Published
2024

3. 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

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

Author

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

Subjects
earthquake source processes, aseismic slip, crustal faulting, numerical modeling, code verification, community benchmarks, Geochemistry, Geology, Geophysics
Abstract

Dynamic modeling of sequences of earthquakes and aseismic slip (SEAS) provides a self-consistent, physics-based framework to connect, interpret, and predict diverse geophysical observations across spatial and temporal scales. Amid growing applications of SEAS models, numerical code verification is essential to ensure reliable simulation results but is often infeasible due to the lack of analytical solutions. Here, we develop two benchmarks for three-dimensional (3D) SEAS problems to compare and verify numerical codes based on boundary-element, finite-element, and finite-difference methods, in a community initiative. Our benchmarks consider a planar vertical strike-slip fault obeying a rate- and state-dependent friction law, in a 3D homogeneous, linear elastic whole-space or half-space, where spontaneous earthquakes and slow slip arise due to tectonic-like loading. We use a suite of quasi-dynamic simulations from 10 modeling groups to assess the agreement during all phases of multiple seismic cycles. We find excellent quantitative agreement among simulated outputs for sufficiently large model domains and small grid spacings. However, discrepancies in rupture fronts of the initial event are influenced by the free surface and various computational factors. The recurrence intervals and nucleation phase of later earthquakes are particularly sensitive to numerical resolution and domain-size-dependent loading. Despite such variability, key properties of individual earthquakes, including rupture style, duration, total slip, peak slip rate, and stress drop, are comparable among even marginally resolved simulations. Our benchmark efforts offer a community-based example to improve numerical simulations and reveal sensitivities of model observables, which are important for advancing SEAS models to better understand earthquake system dynamics.

Published
2022

5. The Community Code Verification Exercise for Simulating Sequences of Earthquakes and Aseismic Slip (SEAS)

Author

Erickson, Brittany A, Jiang, Junle, Barall, Michael, Lapusta, Nadia, Dunham, Eric M, Harris, Ruth, Abrahams, Lauren S, Allison, Kali L, Ampuero, Jean-Paul, Barbot, Sylvain, Cattania, Camilla, Elbanna, Ahmed, Fialko, Yuri, Idini, Benjamin, Kozdon, Jeremy E, Lambert, Valère, Liu, Yajing, Luo, Yingdi, Ma, Xiao, Best McKay, Maricela, Segall, Paul, Shi, Pengcheng, van den Ende, Martijn, and Wei, Meng

Subjects
Geophysics, Geochemistry & Geophysics
Abstract

Numerical simulations of sequences of earthquakes and aseismic slip (SEAS) have made great progress over past decades to address important questions in earthquake physics. However, significant challenges in SEAS modeling remain in resolving multiscale interactions between earthquake nucleation, dynamic rupture, and aseismic slip, and understanding physical factors controlling observables such as seismicity and ground deformation. The increasing complexity of SEAS modeling calls for extensive efforts to verify codes and advance these simulations with rigor, reproducibility, and broadened impact. In 2018, we initiated a community code-verification exercise for SEAS simulations, supported by the Southern California Earthquake Center. Here, we report the findings from our first two benchmark problems (BP1 and BP2), designed to verify different computational methods in solving a mathematically well-defined, basic faulting problem. We consider a 2D antiplane problem, with a 1D planar vertical strike-slip fault obeying rate-and-state friction, embedded in a 2D homogeneous, linear elastic halfspace. Sequences of quasi-dynamic earthquakes with periodic occurrences (BP1) or bimodal sizes (BP2) and their interactions with aseismic slip are simulated. The comparison of results from 11 groups using different numerical methods show excellent agreements in long-term and coseismic fault behavior. In BP1, we found that truncated domain boundaries influence interseismic stressing, earthquake recurrence, and coseismic rupture, and that model agreement is only achieved with sufficiently large domain sizes. In BP2, we found that complexity of fault behavior depends on how well physical length scales related to spontaneous nucleation and rupture propagation are resolved. Poor numerical resolution can result in artificial complexity, impacting simulation results that are of potential interest for characterizing seismic hazard such as earthquake size distributions, moment release, and recurrence times. These results inform the development of more advanced SEAS models, contributing to our further understanding of earthquake system dynamics.

Published
2020

8. Earthquake energy dissipation in a fracture mechanics framework.

Author

Kammer, David S., McLaskey, Gregory C., Abercrombie, Rachel E., Ampuero, Jean-Paul, Cattania, Camilla, Cocco, Massimo, Dal Zilio, Luca, Dresen, Georg, Gabriel, Alice-Agnes, Ke, Chun-Yu, Marone, Chris, Selvadurai, Paul Antony, and Tinti, Elisa

Subjects
ENERGY dissipation, FRACTURE mechanics, LINEAR elastic fracture mechanics, SEISMIC waves, EARTHQUAKES, ROCK mechanics
Abstract

Earthquakes are rupture-like processes that propagate along tectonic faults and cause seismic waves. The propagation speed and final area of the rupture, which determine an earthquake's potential impact, are directly related to the nature and quantity of the energy dissipation involved in the rupture process. Here, we present the challenges associated with defining and measuring the energy dissipation in laboratory and natural earthquakes across many scales. We discuss the importance and implications of distinguishing between energy dissipation that occurs close to and far behind the rupture tip, and we identify open scientific questions related to a consistent modeling framework for earthquake physics that extends beyond classical Linear Elastic Fracture Mechanics. Earthquakes are rupture-like processes that propagate along tectonic faults and cause seismic waves. Here, the authors present the challenges associated with defining and measuring the energy dissipation in laboratory and natural earthquakes across many scales. [ABSTRACT FROM AUTHOR]

Published
2024
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10. 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

11. 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

12. 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

15. 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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17. Precursory Slow Slip and Foreshocks on Rough Faults

Author

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Cattania, Camilla, Segall, Paul, Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences, Cattania, Camilla, and Segall, Paul

Published
2022

18. 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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20. 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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21. 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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23. Community Code Verification Exercise for Simulating Sequences of Earthquakes and Aseismic Slip (SEAS)

Author

Erickson, Brittany A., Jiang, Junle, Barall, Michael, Lapusta, Nadia, Dunham, Eric M., Harris, Ruth, Abrahams, Lauren S., Allison, Kali L., Ampuero, Jean-Paul, Barbot, Sylvain, Cattania, Camilla, Elbanna, Ahmed, Fialko, Yuri, Idini, Benjamín, Kozdon, Jeremy E., Lambert, Valere, Liu, Yajing, Luo, Yingdi, Ma, Xiao, McKay, Maricela Best, Segall, Paul, Shi, Pengcheng, van den Ende, Martijn, and Wei, Meng

Subjects
Physics::Geophysics
Abstract

Numerical simulations of sequences of earthquakes and aseismic slip (SEAS) have made great progress over past decades to address important questions in earthquake physics. However, significant challenges in SEAS modeling remain in resolving multiscale interactions between earthquake nucleation, dynamic rupture, and aseismic slip, and understanding physical factors controlling observables such as seismicity and ground deformation. The increasing complexity of SEAS modeling calls for extensive efforts to verify codes and advance these simulations with rigor, reproducibility, and broadened impact. In 2018, we initiated a community code‐verification exercise for SEAS simulations, supported by the Southern California Earthquake Center. Here, we report the findings from our first two benchmark problems (BP1 and BP2), designed to verify different computational methods in solving a mathematically well‐defined, basic faulting problem. We consider a 2D antiplane problem, with a 1D planar vertical strike‐slip fault obeying rate‐and‐state friction, embedded in a 2D homogeneous, linear elastic half‐space. Sequences of quasi‐dynamic earthquakes with periodic occurrences (BP1) or bimodal sizes (BP2) and their interactions with aseismic slip are simulated. The comparison of results from 11 groups using different numerical methods show excellent agreements in long‐term and coseismic fault behavior. In BP1, we found that truncated domain boundaries influence interseismic stressing, earthquake recurrence, and coseismic rupture, and that model agreement is only achieved with sufficiently large domain sizes. In BP2, we found that complexity of fault behavior depends on how well physical length scales related to spontaneous nucleation and rupture propagation are resolved. Poor numerical resolution can result in artificial complexity, impacting simulation results that are of potential interest for characterizing seismic hazard such as earthquake size distributions, moment release, and recurrence times. These results inform the development of more advanced SEAS models, contributing to our further understanding of earthquake system dynamics.

Published
2020

24. Author Correction: Earthquake energy dissipation in a fracture mechanics framework.

Author

Kammer, David S., McLaskey, Gregory C., Abercrombie, Rachel E., Ampuero, Jean-Paul, Cattania, Camilla, Cocco, Massimo, Dal Zilio, Luca, Dresen, Georg, Gabriel, Alice-Agnes, Ke, Chun-Yu, Marone, Chris, Selvadurai, Paul Antony, and Tinti, Elisa

Subjects
FRACTURE mechanics, ENERGY dissipation, EARTHQUAKES, SOIL mechanics, ROCK mechanics, EUROPEAN communities
Abstract

This document is a correction notice for an article titled "Earthquake energy dissipation in a fracture mechanics framework" published in Nature Communications. The correction addresses an error in the Acknowledgement Section, which failed to include the participation of several individuals in the research project. The corrected version of the article now properly acknowledges the contributions of Massimo Cocco, Paul Selvadurai, Elisa Tinti, and Luca Dal Zilio. The article was authored by David S. Kammer, Gregory C. McLaskey, Rachel E. Abercrombie, Jean-Paul Ampuero, Camilla Cattania, Massimo Cocco, Luca Dal Zilio, Georg Dresen, Alice-Agnes Gabriel, Chun-Yu Ke, Chris Marone, Paul Antony Selvadurai, and Elisa Tinti. [Extracted from the article]

Published
2024
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25. Megathrust Modeling Workshop Report

Author

Dunham, Eric, primary, Thomas, Amanda, additional, Becker, Thorsten, additional, Cattania, Camilla, additional, Hawthorne, Jessica, additional, Hubbard, Judith, additional, Lotto, Gabriel, additional, Olive, Jean-Arthur, additional, and Platt, John, additional

Published
2020
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27. Complex earthquake behavior on simple faults

Author

Cattania, Camilla

Subjects
bepress|Physical Sciences and Mathematics, bepress|Physical Sciences and Mathematics|Earth Sciences|Geophysics and Seismology, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Geophysics and Seismology, bepress|Physical Sciences and Mathematics|Earth Sciences, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences, Physics::Geophysics, EarthArXiv|Physical Sciences and Mathematics
Abstract

While power-law distributions in seismic moment and interevent times are ubiquitous in regional catalogs, the statistics of individual faults remains controversial. Continuum fault models typically produce characteristic earthquakes or a narrow range of sizes, leading to the view that the regional statistics originates from interaction of multiple faults. I present theoretical arguments and numerical simulations demonstrating that seismicity on homogeneous planar faults can span several orders of magnitude in rupture dimensions and interevent times, if the fault dimension W is sufficiently large compared to a characteristic length Lcrit, related to the nucleation dimension. Large faults are increasingly less characteristic, with the fraction of system-size ruptures proportional to (Lcrit/W)^1/2. Earthquake statistics for large W/Lcrit is remarkably close to nature, exhibiting Omori decay and power-law distributed rupture lengths. Simple crack models are consistent with a Gutenberg-Richter distribution with b=3/4, and provide a physical basis for these distributions on individual faults.

Published
2019

29. The Forecasting Skill of Physics‐Based Seismicity Models during the 2010–2012 Canterbury, New Zealand, Earthquake Sequence

Author

Cattania, Camilla, primary, Werner, Maximilian J., additional, Marzocchi, Warner, additional, Hainzl, Sebastian, additional, Rhoades, David, additional, Gerstenberger, Matthew, additional, Liukis, Maria, additional, Savran, William, additional, Christophersen, Annemarie, additional, Helmstetter, Agnès, additional, Jimenez, Abigail, additional, Steacy, Sandy, additional, and Jordan, Thomas H., additional

Published
2018
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31. Dynamic triggering and earthquake swarms on East Pacific Rise transform faults

Author

Cattania, Camilla, McGuire, Jeffrey J., Collins, John A., Cattania, Camilla, McGuire, Jeffrey J., and Collins, John A.

Abstract

While dynamic earthquake triggering has been reported in several continental settings, offshore observations are rare. Oceanic transform faults share properties with continental geothermal areas known for dynamic triggering: high geothermal gradients, high seismicity rates, and frequent swarms. We study dynamic triggering along the East Pacific Rise by analyzing 1 year of seismicity recorded by Ocean Bottom Seismographs. By comparing the response to teleseismic waves from global earthquakes, we find triggering to be most sensitive to changes in normal stress and to preferentially occur above 0.25 kPa. The clearest example of triggering occurs on the Quebrada and Gofar faults after the Mw8.0 Wenchuan earthquake. On Gofar, triggered seismicity occurs between the rupture areas of large earthquakes, within a zone characterized by aseismic slip, abundant microseismicity, frequent swarms, and low Vp. We infer that lithological properties inhibiting rupture propagation, such as high porosity and fluid content, also favor dynamic triggering.

Published
2017

35. Verbesserte Nachbebenmodelle durch Berücksichtigung von Coulombspannungsänderungen und Rate-State abhängiger Reibung

Author

Cattania, Camilla

Subjects
pacs:90.00.00, ddc:550, Institut für Geowissenschaften
Abstract

Earthquake clustering has proven the most useful tool to forecast changes in seismicity rates in the short and medium term (hours to months), and efforts are currently being made to extend the scope of such models to operational earthquake forecasting. The overarching goal of the research presented in this thesis is to improve physics-based earthquake forecasts, with a focus on aftershock sequences. Physical models of triggered seismicity are based on the redistribution of stresses in the crust, coupled with the rate-and-state constitutive law proposed by Dieterich to calculate changes in seismicity rate. This type of models are known as Coulomb- rate and-state (CRS) models. In spite of the success of the Coulomb hypothesis, CRS models typically performed poorly in comparison to statistical ones, and they have been underepresented in the operational forecasting context. In this thesis, I address some of these issues, and in particular these questions: (1) How can we realistically model the uncertainties and heterogeneity of the mainshock stress field? (2) What is the effect of time dependent stresses in the postseismic phase on seismicity? I focus on two case studies from different tectonic settings: the Mw 9.0 Tohoku megathrust and the Mw 6.0 Parkfield strike slip earthquake. I study aleatoric uncertainties using a Monte Carlo method. I find that the existence of multiple receiver faults is the most important source of intrinsic stress heterogeneity, and CRS models perform better when this variability is taken into account. Epistemic uncertainties inherited from the slip models also have a significant impact on the forecast, and I find that an ensemble model based on several slip distributions outperforms most individual models. I address the role of postseismic stresses due to aseismic slip on the mainshock fault (afterslip) and to the redistribution of stresses by previous aftershocks (secondary triggering). I find that modeling secondary triggering improves model performance. The effect of afterslip is less clear, and difficult to assess for near-fault aftershocks due to the large uncertainties of the afterslip models. Off-fault events, on the other hand, are less sensitive to the details of the slip distribution: I find that following the Tohoku earthquake, afterslip promotes seismicity in the Fukushima region. To evaluate the performance of the improved CRS models in a pseudo-operational context, I submitted them for independent testing to a collaborative experiment carried out by CSEP for the 2010-2012 Canterbury sequence. Preliminary results indicate that physical models generally perform well compared to statistical ones, suggesting that CRS models may have a role to play in the future of operational forecasting. To facilitate efforts in this direction, and to enable future studies of earthquake triggering by time dependent processes, I have made the code open source. In the final part of this thesis I summarize the capabilities of the program and outline technical aspects regarding performance and parallelization strategies. Die örtliche und zeitlich Häufung von Erdbeben ist geeignet, um Änderungen in Seismizitätsraten auf kurzen bis mittleren Zeitskalen (Stunden bis Monate) zu prognostizieren. Kürzlich wurden vermehrt Anstrengungen unternommen, den Umfang solcher Modelle auf Operationelle Erdbebenvorhersage auszudehnen, welche die Veröffentlichung von Erdbebenwahrscheinlichkeiten beinhaltet mit dem Ziel, die Bevölkerung besser auf mögliche Erdbeben vorzubereiten. Das vorrangige Ziel dieser Dissertation ist die Verbesserung von kurz- und mittelfristiger Erdbebenprognose basierend auf physikalischen Modellen. Ich konzentriere mich hier auf Nachbebensequenzen. Physikalische Modelle, die getriggerte Seimizität erklären, basieren auf der Umverteilung von Spannungen in der Erdkruste. Berechnung der Coulomb Spannung können kombiniert werden mit dem konstituivem Gesetz von Dieterich, welches die Berechnung von Änderungen in der Seismizitätsrate ermöglicht. Diese Modelle sind als Coulomb-Rate-and-State (CRS) Modelle bekannt. Trotz der erfolgreichen Überprüfung der Coulomb-Hypothese, schneiden CRS-Modelle im Vergleich mit statistischen Modellen schlecht ab, und wurden deshalb bisher kaum im Kontext operationeller Erdbenbenvorhersage genutzt. In dieser Arbeit, gehe ich auf einige der auftretenden Probleme ein. Im Besonderen wende ich mich den folgenden Fragen zu: (1) Wie können wir die Unsicherheiten und die Heterogenität des Spannungsfeldes infolge des Hauptbebens realistisch modellieren? (2)Welche Auswirkungen haben zeitlich variable Spannungsänderungen in der postseismischen Phase? Ich konzentriere mich hierbei auf zwei Beispiele in unterschiedlichen tektonischen Regionen: die Aufschiebung des Mw9.0 Tohoku Erdbeben und die Blattverschiebung des Mw6.0 Parkfield Erdbeben. Ich untersuche aleotorische Unsicherheiten der Coulomb-Spannung durch Variabilität in der Orientierung der betroffenen Bruchflächen und durch Spannungsgradienten innerhalb von Modellzellen. Ich zeige, dass die Existenz der unterschiedlichen Bruchflächen die bedeutenste Quelle für intrinsiche Spannungheterogenität ist und das CRS-Modelle deutlich besser abschneiden, wenn diese Variabilität berücksichtigt wird. Die epistemischen Unsicherheiten aufgrund von unterschiedlichen Ergebnissen von Inversionen von Daten für die Verschiebung entlang der Bruchfläche haben ebenso erhebliche Auswirkungen auf die Vorhersage. Ich gehe dann auf die Rolle von postseismischen Spannung ein, insbesondere auf zwei Prozesse: aseismische Verschiebung entlang der Störungsfläche des Hauptbebens (Afterslip) und die Veränderung von Spannungen durch vorhergehende Nachbeben (sekundäres Triggern). Ich demonstriere, dass das Modellieren von sekundärem Triggern die Modellvorhersage in beiden Fallbeispielen verbessert. Die Einbeziehung von Afterslip verbessert die Qualität der Vorhersage nur für die Nachbebensequenz des Parkfield Erdbebens. Dagegen kann ich nachweisen, dass Afterslip infolge des Tohoku Bebens eine höhere Seismizität auf Abschiebungsflächen im Hangenden begünstigt. Die dargestellten Verbesserungen des CRS-Modells sind sehr vielversprechend im Kontext operationeller Erdbebenvorhersage, verlangen aber nach weiterer Überprüfung. Ich stelle die vorläufigen Ergebnisse eines gemeinschaftlichen Tests für die Erdbebenfolge von Canterbury 2010-2012 vor, welcher von CSEP durchgeführt wurde. Die physikalischen Modelle schneiden hier im Vergleich mit statistischen Modellen gut ab. Daher scheint eine Anwendung von CSR-Modellen, die Unsicherheiten und sekundäres Triggering berücksichtigen, in zukünftigen operationellen Erdbebenvorhersagen empfehlenswert. Um die Bemühungen in dieser Richtung zu unterstützen und weitere Studien zum Triggern von Erdbeben durch zeitabhängige Prozesse zu ermöglichen, habe ich meinen Open Source Code öffentlich zugänglich gemacht. Im letzen Teil dieser Arbeit fasse ich die Leistungsfähigkeit des Programms zusammen und skizziere die technischen Aspekte bezüglich der Effiziens und der Parallelisierung des Programmes.

Published
2015

38. A nonplanar slow rupture episode during the 2000 Miyakejima dike intrusion

Author

Cattania, C., Rivalta, E., Hainzl, S., Passarelli, L., Aoki, Y., Cattania, Camilla, Rivalta, Eleonora, Hainzl, Sebastian, Passarelli, Luigi, and Aoki, Yosuke

Subjects
dike intrusion Miyakejima dike dike‐induced seismicity slow slip
Abstract

Magmatic intrusions release extensional strain in the Earth's crust upon availability of magma. Intrusions are typically accompanied by earthquake swarms and by surface faulting that is often larger than what is expected from the magnitude of the induced earthquakes. The 2000 Miyakejima dike intrusion triggered the largest volcanic earthquake swarm monitored so far, with five Ml>6 earthquakes. We analyze the seismicity and deformation induced by the Miyakejima dike with the aim of constraining the timescale and mechanisms of slow strain release during the episode. In six earthquake bursts lasting few hours and migrating at ∼1 km h−1 we find candidates for slow earthquakes. Each burst nucleated at the tips of previous bursts, suggesting stress interaction. The variability of fault plane solutions indicates that the bursts occurred on a complex system of fractures, consistent with weakly consolidated surface layers strained by spatially inhomogneous stresses that change in time, such as those induced by a dike. Based on dislocation models, we find that deformation is best explained by aseismic slip (in addition to the seismic burst), with a moment 1.3 to 2.3 times larger than the earthquakes' seismic moment, and opening of 0.20 ± 0.07 m on the dike. The aseismic slip occurred over a few hours, with moment, duration, and migration velocity consistent with that of previously observed slow slip events. We argue that the seismic bursts are likely driven by slow slip, sharing most properties with tectonic slow slip events and swarms, but occurring on a set of nonaligned faults.

Published
2017

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