Crack to pulse transition and magnitude statistics during earthquake cycles on a self-similar rough fault

Heimisson, Elías Rafn

doi:10.1016/j.epsl.2020.116202

Cited by 29 publications

(25 citation statements)

References 36 publications

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“…A similar transition from few large ruptures to many smaller ones was found by Heimisson (2020) when increasing k max ; since the amplitude of normal stress perturbations grows with k max (Equation 10), this is consistent with our findings. Similarly, we expect that increasing fault roughness would have the same effect, since Δ σ rms increases with the product of roughness and accrued slip.…”

Section: Discussionsupporting

confidence: 93%

“…Perhaps the most ubiquitous and best characterized source of heterogeneity is geometrical roughness: faults are fractal surfaces (Brodsky et al., 2016; Candela et al., 2009, 2012; Power & Tullis, 1991; Power et al., 1987, 1988; Sagy et al., 2007). Numerical and theoretical studies have shown that fault roughness has a first‐order effect on rupture nucleation (Tal et al., 2018), as well as propagation and arrest (Dunham et al., 2011; Fang & Dunham, 2013; Heimisson, 2020; Ozawa et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

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Precursory Slow Slip and Foreshocks on Rough Faults

2021

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Foreshocks are not uncommon prior to large earthquakes, but their physical mechanism remains controversial. Two interpretations have been advanced: (1) foreshocks are driven by aseismic nucleation and (2) foreshocks are cascades, with each event triggered by earlier ones. Here, we study seismic cycles on faults with fractal roughness at wavelengths exceeding the nucleation length. We perform 2‐D quasi‐dynamic, elastic simulations of frictionally uniform rate‐state faults. Roughness leads to a range of slip behavior between system‐size ruptures, including widespread creep, localized slow slip, and microseismicity. These processes are explained by spatial variations in normal stress (σ) caused by roughness: regions with low σ tend to creep, while high σ regions remain locked until they break seismically. Foreshocks and mainshocks both initiate from the rupture of locked asperities, but mainshocks preferentially start on stronger asperities. The preseismic phase is characterized by feedback between creep and foreshocks: episodic seismic bursts break groups of nearby asperities, causing creep to accelerate, which in turns loads other asperities leading to further foreshocks. A simple analytical treatment of this mutual stress transfer, confirmed by simulations, predicts slip velocities and seismicity rates increase as 1/t, where t is the time to the mainshock. The model reproduces the observed migration of foreshocks toward the mainshock hypocenter, foreshock locations consistent with static stress changes, and the 1/t acceleration in stacked catalogs. Instead of interpreting foreshocks as either driven by coseismic stress changes or by creep, we propose that earthquake nucleation on rough faults is driven by the feedback between the two.

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Section: Discussionsupporting

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Precursory Slow Slip and Foreshocks on Rough Faults

2021

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“…Slip on a rough fault produces an additional shear resistance, which is expressed as

τ_{d r a g} = {false(2 π false)}^{3} α^{2} G δ / λ_{m i n},

where δ is slip and H is the Hurst exponent. Roughness drag enhances pulse‐like ruptures and deviation from the classical elliptic crack (Dieterich & Smith, 2009; Heimisson, 2020), which reduces the stress concentration at the fault tips.…”

Section: Resultsmentioning

confidence: 99%

“…The pulse‐like ruptures only occur and the effect of roughness drag is only important if the rupture length is larger than λ min /(4 π 4 α 2 ) (Heimisson, 2020). Otherwise, the classical elliptic crack is realized and the stress concentration around the tips is strong.…”

Section: Resultsmentioning

confidence: 99%

Mainshock and Aftershock Sequence Simulation in Geometrically Complex Fault Zones

Ozawa

Ando

2021

JGR Solid Earth

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The complexity of natural fault zones has been a target of numerous studies (Ben-Zion & Sammis, 2003; Faulkner et al., 2010). Although often simplified as a single flat surface in modeling, natural faults have complicated geometry. Faults are typically composed of a few discontinuous segments at a wide range of scales (Manighetti et al., 2015; Segall & Pollard, 1980). Each continuous slip surface has deviation from planarity over broad spatial scales. The fractal-like geometrical irregularity of fault surfaces is referred to as fault roughness and is documented from various observations (

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“…Recently, Tarduno et al (2015) argued that SAMA is being created by a topography structure in the CMB beneath southern Africa. Not only is SAMA linked with global magnetic features such as a geomagnetic dipole moment (e.g., Heirtzler, 2002;Gubbins et al, 2006), it also corresponds to the closer area between the Earth's surface and radiation belt. This proximity allows more charged particles and more disturbances in the magnetic field near the Chilean margin (e.g., Kivelson and Russell, 1995).…”

Section: Secular Variation In the Chilean Convergent Marginmentioning

confidence: 99%

Long-term magnetic anomalies and their possible relationship to the latest greater Chilean earthquakes in the context of the seismo-electromagnetic theory

Cordaro

Venegas-Aravena

Laroze

2021

Nat. Hazards Earth Syst. Sci.

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Abstract. Several magnetic measurements and theoretical developments from different research groups have shown certain relationships with worldwide geological processes. Secular variation in geomagnetic cutoff rigidity, magnetic frequencies, or magnetic anomalies have been linked with spatial properties of active convergent tectonic margins or earthquake occurrences during recent years. These include the rise in similar fundamental frequencies in the range of microhertz before the Maule 2010, Tōhoku 2011, and Sumatra–Andaman 2004 earthquakes and the dramatic rise in the cumulative number of magnetic anomalous peaks before several earthquakes such as Nepal 2015 and Mexico (Puebla) 2017. Currently, all of these measurements have been physically explained by the microcrack generation due to uniaxial stress change in rock experiments. The basic physics of these experiments have been used to describe the lithospheric behavior in the context of the seismo-electromagnetic theory. Due to the dramatic increase in experimental evidence, physical mechanisms, and the theoretical framework, this paper analyzes vertical magnetic behavior close to the three latest main earthquakes in Chile: Maule 2010 (Mw 8.8), Iquique 2014 (Mw 8.2), and Illapel 2015 (Mw 8.3). The fast Fourier transform (FFT), wavelet transform, and daily cumulative number of anomalies methods were used during quiet space weather time during 1 year before and after each earthquake in order to filter space influence. The FFT method confirms the rise in the power spectral density in the millihertz range 1 month before each earthquake, which decreases to lower values some months after earthquake occurrence. The cumulative anomaly method exhibited an increase prior to each Chilean earthquake (50–90 d prior to earthquakes) similar to those found for Nepal 2015 and Mexico 2017. The wavelet analyses also show similar properties to FFT analysis. However, the lack of physics-based constraints in the wavelet analysis does not allow conclusions that are as strong as those made by FFT and cumulative methods. By using these results and previous research, it could be stated that these magnetic features could give seismic information about impending events. Additionally, these results could be related to the lithosphere–atmosphere–ionosphere coupling (LAIC effect) and the growth of microcracks and electrification in rocks described by the seismo-electromagnetic theory.

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Crack to pulse transition and magnitude statistics during earthquake cycles on a self-similar rough fault

Cited by 29 publications

References 36 publications

Precursory Slow Slip and Foreshocks on Rough Faults

Precursory Slow Slip and Foreshocks on Rough Faults

Mainshock and Aftershock Sequence Simulation in Geometrically Complex Fault Zones

Long-term magnetic anomalies and their possible relationship to the latest greater Chilean earthquakes in the context of the seismo-electromagnetic theory

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