Long-range automaton models of earthquakes: Power-law accelerations, correlation evolution, and mode-switching

D. Weatherley; P. Mora; M. F. Xia

doi:10.1007/s00024-002-8743-6

Long-range automaton models of earthquakes: Power-law accelerations, correlation evolution, and mode-switching

D. Weatherley^*
, P. Mora
, M. F. Xia

^*Corresponding author for this work

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

24 Scopus citations

Abstract

We introduce a conceptual model for the in-plane physics of an earthquake fault. The model employs cellular automaton techniques to simulate tectonic loading, earthquake rupture, and strain redistribution. The impact of a hypothetical crustal elastodynamic Green's function is approximated by a long-range strain redistribution law with a r^-p dependance. We investigate the influence of the effective elastodynamic interaction range upon the dynamical behaviour of the model by conducting experiments with different values of the exponent (p). The results indicate that this model has two distinct, stable modes of behaviour. The first mode produces a characteristic earthquake distribution with moderate to large events preceeded by an interval of time in which the rate of energy release accelerates. A correlation function analysis reveals that accelerating sequences are associated with a systematic, global evolution of strain energy correlations within the system. The second stable mode produces Gutenberg-Richter statistics, with near-linear energy release and no significant global correlation evolution. A model with effectively short-range interactions preferentially displays Gutenberg-Richter behaviour. However, models with long-range interactions appear to switch between the characteristic and GR modes. As the range of clastodynamic interactions is increased, characteristic behaviour begins to dominate GR behaviour. These models demonstrate that evolution of strain energy correlations may occur within systems with a fixed elastodynamic interaction range. Supposing that similar mode-switching dynamical behaviour occurs within earthquake faults then intermediate-term forecasting of large earthquakes may be feasible for some earthquakes but not for others, in alignment with certain empirical seismological observations. Further numerical investigation of dynamical models of this type may lead to advances in earthquake forecasting research and theoretical seismology.

Original language	English
Pages (from-to)	2469-2490
Number of pages	22
Journal	Pure and Applied Geophysics
Volume	159
Issue number	10
DOIs	https://doi.org/10.1007/s00024-002-8743-6
State	Published - 2002
Externally published	Yes

Bibliographical note

Funding Information:
This research was supported by the Australian Research Council, the University of Queensland, the Special Funds for Major State Basic Research Project and the National Natural Science Foundation of China (Grant No. 19732060 and No. 19972004), and the ARC IREX ACES International Visitors Program. The authors wish to thank W. Klein and Y. Ben-Zion for insightful discussions and advice during this research project. Thanks also to the reviewers for constructive criticism of the original manuscript.

Keywords

Cellular automata
Correlation evolution
Critical point hypothesis

ASJC Scopus subject areas

Geophysics
Geochemistry and Petrology

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10.1007/s00024-002-8743-6

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@article{15c0fc9cc6434b429c8a676514de4ac5,

title = "Long-range automaton models of earthquakes: Power-law accelerations, correlation evolution, and mode-switching",

abstract = "We introduce a conceptual model for the in-plane physics of an earthquake fault. The model employs cellular automaton techniques to simulate tectonic loading, earthquake rupture, and strain redistribution. The impact of a hypothetical crustal elastodynamic Green's function is approximated by a long-range strain redistribution law with a r-p dependance. We investigate the influence of the effective elastodynamic interaction range upon the dynamical behaviour of the model by conducting experiments with different values of the exponent (p). The results indicate that this model has two distinct, stable modes of behaviour. The first mode produces a characteristic earthquake distribution with moderate to large events preceeded by an interval of time in which the rate of energy release accelerates. A correlation function analysis reveals that accelerating sequences are associated with a systematic, global evolution of strain energy correlations within the system. The second stable mode produces Gutenberg-Richter statistics, with near-linear energy release and no significant global correlation evolution. A model with effectively short-range interactions preferentially displays Gutenberg-Richter behaviour. However, models with long-range interactions appear to switch between the characteristic and GR modes. As the range of clastodynamic interactions is increased, characteristic behaviour begins to dominate GR behaviour. These models demonstrate that evolution of strain energy correlations may occur within systems with a fixed elastodynamic interaction range. Supposing that similar mode-switching dynamical behaviour occurs within earthquake faults then intermediate-term forecasting of large earthquakes may be feasible for some earthquakes but not for others, in alignment with certain empirical seismological observations. Further numerical investigation of dynamical models of this type may lead to advances in earthquake forecasting research and theoretical seismology.",

keywords = "Cellular automata, Correlation evolution, Critical point hypothesis",

author = "D. Weatherley and P. Mora and Xia, \{M. F.\}",

note = "Funding Information: This research was supported by the Australian Research Council, the University of Queensland, the Special Funds for Major State Basic Research Project and the National Natural Science Foundation of China (Grant No. 19732060 and No. 19972004), and the ARC IREX ACES International Visitors Program. The authors wish to thank W. Klein and Y. Ben-Zion for insightful discussions and advice during this research project. Thanks also to the reviewers for constructive criticism of the original manuscript.",

year = "2002",

doi = "10.1007/s00024-002-8743-6",

language = "English",

volume = "159",

pages = "2469--2490",

journal = "Pure and Applied Geophysics",

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T1 - Long-range automaton models of earthquakes

T2 - Power-law accelerations, correlation evolution, and mode-switching

AU - Weatherley, D.

AU - Mora, P.

AU - Xia, M. F.

N1 - Funding Information: This research was supported by the Australian Research Council, the University of Queensland, the Special Funds for Major State Basic Research Project and the National Natural Science Foundation of China (Grant No. 19732060 and No. 19972004), and the ARC IREX ACES International Visitors Program. The authors wish to thank W. Klein and Y. Ben-Zion for insightful discussions and advice during this research project. Thanks also to the reviewers for constructive criticism of the original manuscript.

PY - 2002

Y1 - 2002

N2 - We introduce a conceptual model for the in-plane physics of an earthquake fault. The model employs cellular automaton techniques to simulate tectonic loading, earthquake rupture, and strain redistribution. The impact of a hypothetical crustal elastodynamic Green's function is approximated by a long-range strain redistribution law with a r-p dependance. We investigate the influence of the effective elastodynamic interaction range upon the dynamical behaviour of the model by conducting experiments with different values of the exponent (p). The results indicate that this model has two distinct, stable modes of behaviour. The first mode produces a characteristic earthquake distribution with moderate to large events preceeded by an interval of time in which the rate of energy release accelerates. A correlation function analysis reveals that accelerating sequences are associated with a systematic, global evolution of strain energy correlations within the system. The second stable mode produces Gutenberg-Richter statistics, with near-linear energy release and no significant global correlation evolution. A model with effectively short-range interactions preferentially displays Gutenberg-Richter behaviour. However, models with long-range interactions appear to switch between the characteristic and GR modes. As the range of clastodynamic interactions is increased, characteristic behaviour begins to dominate GR behaviour. These models demonstrate that evolution of strain energy correlations may occur within systems with a fixed elastodynamic interaction range. Supposing that similar mode-switching dynamical behaviour occurs within earthquake faults then intermediate-term forecasting of large earthquakes may be feasible for some earthquakes but not for others, in alignment with certain empirical seismological observations. Further numerical investigation of dynamical models of this type may lead to advances in earthquake forecasting research and theoretical seismology.

AB - We introduce a conceptual model for the in-plane physics of an earthquake fault. The model employs cellular automaton techniques to simulate tectonic loading, earthquake rupture, and strain redistribution. The impact of a hypothetical crustal elastodynamic Green's function is approximated by a long-range strain redistribution law with a r-p dependance. We investigate the influence of the effective elastodynamic interaction range upon the dynamical behaviour of the model by conducting experiments with different values of the exponent (p). The results indicate that this model has two distinct, stable modes of behaviour. The first mode produces a characteristic earthquake distribution with moderate to large events preceeded by an interval of time in which the rate of energy release accelerates. A correlation function analysis reveals that accelerating sequences are associated with a systematic, global evolution of strain energy correlations within the system. The second stable mode produces Gutenberg-Richter statistics, with near-linear energy release and no significant global correlation evolution. A model with effectively short-range interactions preferentially displays Gutenberg-Richter behaviour. However, models with long-range interactions appear to switch between the characteristic and GR modes. As the range of clastodynamic interactions is increased, characteristic behaviour begins to dominate GR behaviour. These models demonstrate that evolution of strain energy correlations may occur within systems with a fixed elastodynamic interaction range. Supposing that similar mode-switching dynamical behaviour occurs within earthquake faults then intermediate-term forecasting of large earthquakes may be feasible for some earthquakes but not for others, in alignment with certain empirical seismological observations. Further numerical investigation of dynamical models of this type may lead to advances in earthquake forecasting research and theoretical seismology.

KW - Cellular automata

KW - Correlation evolution

KW - Critical point hypothesis

UR - https://www.scopus.com/pages/publications/0036041174

U2 - 10.1007/s00024-002-8743-6

DO - 10.1007/s00024-002-8743-6

M3 - Article

AN - SCOPUS:0036041174

SN - 0033-4553

VL - 159

SP - 2469

EP - 2490

JO - Pure and Applied Geophysics

JF - Pure and Applied Geophysics

IS - 10

ER -

Long-range automaton models of earthquakes: Power-law accelerations, correlation evolution, and mode-switching

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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