The Lattice Solid Model to Simulate the Physics of Rocks and Earthquakes: Incorporation of Friction

David Place; Peter Mora

doi:10.1006/jcph.1999.6184

The Lattice Solid Model to Simulate the Physics of Rocks and Earthquakes: Incorporation of Friction

David Place^*
, Peter Mora

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

90 Scopus citations

Abstract

The particle-based lattice solid model developed to study the physics of rocks and the nonlinear dynamics of earthquakes is refined by incorporating intrinsic friction between particles. The model provides a means for studying the causes of seismic wave attenuation, as well as frictional heat generation, fault zone evolution, and localisation phenomena. A modified velocity-Verlat scheme that allows friction to be precisely modelled is developed. This is a difficult computational problem given that a discontinuity must be accurately simulated by the numerical approach (i.e., the transition from static to dynamical frictional behaviour). This is achieved using a half time step integration scheme. At each half time step, a nonlinear system is solved to compute the static frictional forces and states of touching particle-pairs. Improved efficiency is achieved by adaptively adjusting the time step increment, depending on the particle velocities in the system. The total energy is calculated and verified to remain constant to a high precision during simulations. Numerical experiments show that the model can be applied to the study of earthquake dynamics, the stick-slip instability, heat generation, and fault zone evolution. Such experiments may lead to a conclusive resolution of the heat flow paradox and improved understanding of earthquake precursory phenomena and dynamics.

Original language	English
Pages (from-to)	332-372
Number of pages	41
Journal	Journal of Computational Physics
Volume	150
Issue number	2
DOIs	https://doi.org/10.1006/jcph.1999.6184
State	Published - 10 Apr 1999
Externally published	Yes

Bibliographical note

Funding Information:
The research was funded by the Australian Research Council. Supplementary funding was provided by The University of Queensland (UQ), the sponsor of QUAKES. Principle computations were made using the QUAKES 12 processor, Silicon Graphics Origin 2000. Supplementary and seed computations were made using respectively UQ’s Power Challenge, the QUAKES Power Challenge; and the CM-5 of the French National Centre for Parallel Computing in the Earth Sciences (CNCPST). We thank P. A. Cundall for an insightful, comprehensive, and constructive review.

Keywords

Earthquakes
Fault gouge
Friction
Heat flow paradox
Heat of earthquakes
Lattice solid model
Nonlinear dynamics
Numerical simulation
Particle-based model
Rock physics

ASJC Scopus subject areas

Numerical Analysis
Modeling and Simulation
Physics and Astronomy (miscellaneous)
General Physics and Astronomy
Computer Science Applications
Computational Mathematics
Applied Mathematics

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10.1006/jcph.1999.6184

Cite this

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title = "The Lattice Solid Model to Simulate the Physics of Rocks and Earthquakes: Incorporation of Friction",

abstract = "The particle-based lattice solid model developed to study the physics of rocks and the nonlinear dynamics of earthquakes is refined by incorporating intrinsic friction between particles. The model provides a means for studying the causes of seismic wave attenuation, as well as frictional heat generation, fault zone evolution, and localisation phenomena. A modified velocity-Verlat scheme that allows friction to be precisely modelled is developed. This is a difficult computational problem given that a discontinuity must be accurately simulated by the numerical approach (i.e., the transition from static to dynamical frictional behaviour). This is achieved using a half time step integration scheme. At each half time step, a nonlinear system is solved to compute the static frictional forces and states of touching particle-pairs. Improved efficiency is achieved by adaptively adjusting the time step increment, depending on the particle velocities in the system. The total energy is calculated and verified to remain constant to a high precision during simulations. Numerical experiments show that the model can be applied to the study of earthquake dynamics, the stick-slip instability, heat generation, and fault zone evolution. Such experiments may lead to a conclusive resolution of the heat flow paradox and improved understanding of earthquake precursory phenomena and dynamics.",

keywords = "Earthquakes, Fault gouge, Friction, Heat flow paradox, Heat of earthquakes, Lattice solid model, Nonlinear dynamics, Numerical simulation, Particle-based model, Rock physics",

author = "David Place and Peter Mora",

note = "Funding Information: The research was funded by the Australian Research Council. Supplementary funding was provided by The University of Queensland (UQ), the sponsor of QUAKES. Principle computations were made using the QUAKES 12 processor, Silicon Graphics Origin 2000. Supplementary and seed computations were made using respectively UQ{\textquoteright}s Power Challenge, the QUAKES Power Challenge; and the CM-5 of the French National Centre for Parallel Computing in the Earth Sciences (CNCPST). We thank P. A. Cundall for an insightful, comprehensive, and constructive review.",

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The Lattice Solid Model to Simulate the Physics of Rocks and Earthquakes: Incorporation of Friction

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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