Precursory Slow Slip and Foreshocks on Rough Faults

Cattania, Camilla; Segall, P.

doi:10.1029/2020jb020430

Cited by 106 publications

(126 citation statements)

References 77 publications

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“…Our observations are reminiscent of those of acoustic emissions in laboratory experiments, where the underlying precursory aseismic fault slip was measured directly (e.g., Bolton et al, 2019;Goebel et al, 2013;Rouet-Leduc et al, 2017). Recent theoretical models (e.g., Cattania & Segall, 2021) further substantiate this interpretation.…”

Section: Discussionsupporting

confidence: 73%

Possible Precursory Slow‐Slip to Two M_L∼3 Mainevents of the Diemtigen Microearthquake Sequence, Switzerland

Simon

Diehl

Tormann³

2021

Geophysical Research Letters

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How earthquakes initiate is still a largely debated question in earthquake science. On the lab scale, rupture initiation is well studied, and detailed models of how rupture nucleation evolves have been developed. Contrarily, for real earthquakes, only a few high‐resolution observations of this process are available today, mostly limited to mainshock magnitudes > M5. Consequently, there is still no consensus on whether and how laboratory results can be transferred to real earthquakes. Here we show that rupture nucleation phenomena observed on the lab scale can also be imaged on the microearthquake‐scale with little instrumental effort. Our results highlight the potential of the applied analysis workflow to significantly improve the observation quality of seismicity patterns and immediate foreshock phenomena in microearthquake sequences. Our approach can help to narrow the existing observational gap to the lab scale and may contribute to a better understanding of the mechanisms of earthquake initiation in the future.

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Section: Discussionsupporting

confidence: 73%

Possible Precursory Slow‐Slip to Two M_L∼3 Mainevents of the Diemtigen Microearthquake Sequence, Switzerland

Simon

Diehl

Tormann³

2021

Geophysical Research Letters

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“…Our modeling shows that increasingly efficient dynamic weakening leads to different earthquake statistics, with fewer small events and increasing number of large events. Another factor that can significantly affect the ability of earthquake ruptures to propagate is fault heterogeneity, including variations in the rate-andstate frictional properties, effective normal stress, and fault roughness (e.g., Ampuero et al, 2006;Cattania & Segall, 2021;Heimisson, 2020;Hillers et al, 2006Hillers et al, , 2007Schaal & Lapusta, 2019). Some dynamic heterogeneity in shear stress spontaneously develops in our simulations, leading to a broad distribution of event sizes for cases with mild to moderate enhanced dynamic weakening.…”

Section: Discussionmentioning

confidence: 91%

“…Another factor that can significantly affect the ability of earthquake ruptures to propagate is fault heterogeneity, including variations in the rate-and-state frictional properties, effective normal stress, and fault roughness (e.g. Hillers et al, 2006Hillers et al, , 2007Ampuero et al, 2006;Schaal & Lapusta, 2019;Heimisson, 2020;Cattania & Segall, 2021). Some dynamic heterogeneity in shear stress spontaneously develops in our simulations, leading to a broad distribution of event sizes for cases with mild to moderate enhanced dynamic weakening.…”

Section: Accepted Articlementioning

confidence: 90%

Scale Dependence of Earthquake Rupture Prestress in Models With Enhanced Weakening: Implications for Event Statistics and Inferences of Fault Stress

2021

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Local shear prestress varies significantly within and among ruptures, being close 10 to the quasi-static fault strength in nucleation regions. 11• Efficient weakening allows rupture propagation over areas of lower prestress, lead-12 ing to lower average prestress over larger rupture areas. 13• Fault models with more efficient dynamic weakening produce fewer smaller events 14 and result in systematically lower b-values.

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“…In this view, our "main asperity" is not a purely rate-weakening frictional patch surrounded by rate-strengthening material (T. Chen & Lapusta, 2009;Johnson & Nadeau, 2002), but a superposition of nearly simultaneous ruptures at many smaller asperities with a spatially constant location of rupture initiation. Some hypotheses explaining such behavior may be, for example, locally higher normal stress (Cattania & Segall, 2021) or regions that exhibit lower levels of fracture surface energy (Ide & Aochi, 2005;Noda et al, 2013). This is supported by one event at the end of the main asperity's active period that shows a magnitude 20 times weaker than typical events, indicating that it may have only ruptured a subset of weak asperities.…”

Section: Sub-structure Of the Stick-slip Asperitymentioning

confidence: 93%

Fine Structure of Microseismic Glacial Stick‐Slip

Gräff

Köpfli

Lipovsky

et al. 2021

Geophysical Research Letters

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The role of seismogenic glacier sliding in ice sheet flow is debated (Minchew et al., 2019;Stearns & Van der Veen, 2018). Accumulating evidence suggests that glacier basal motion is not exclusively smooth and slow as traditional theories propose (Kamb, 1970;Weertman, 1957). Instead, sudden and irregular stick-slip episodes clustering at distinct "asperities" are part of ice flow dynamics, and individual slip events range in size between microseismic scales and ice-stream-wide displacements (Anandakrishnan & Alley, 1994; for a review: Aster & Winberry, 2017;Wiens et al., 2008). In analogy to tectonic faults in the Earth's crust, frictional processes are thus present at the bed of glaciers (Kufner et al., 2021;McBrearty et al., 2020; for a review: Podolskiy & Walter, 2016), with stick-slip "icequakes" representing the release of gravitational elastic loading at the interface between ice and the underlying bed. Analogous to creeping and locked fault sections that control relative motion of tectonic plates (K. H. Chen & Bürgmann, 2017;Harris, 2017), smooth sliding and stick-slip motion may regulate the basal sliding of glaciers (Anandakrishnan & Bentley, 1993).The understanding of seismogenic sliding's role within large-scale ice dynamics is still limited. For microseismic stick-slip icequakes, which generally seem to accompany glacier sliding (e.g.,

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Precursory Slow Slip and Foreshocks on Rough Faults

Cited by 106 publications

References 77 publications

Possible Precursory Slow‐Slip to Two M_L∼3 Mainevents of the Diemtigen Microearthquake Sequence, Switzerland

Possible Precursory Slow‐Slip to Two M_L∼3 Mainevents of the Diemtigen Microearthquake Sequence, Switzerland

Scale Dependence of Earthquake Rupture Prestress in Models With Enhanced Weakening: Implications for Event Statistics and Inferences of Fault Stress

Fine Structure of Microseismic Glacial Stick‐Slip

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Precursory Slow Slip and Foreshocks on Rough Faults

Cited by 106 publications

References 77 publications

Possible Precursory Slow‐Slip to Two ML∼3 Mainevents of the Diemtigen Microearthquake Sequence, Switzerland

Possible Precursory Slow‐Slip to Two ML∼3 Mainevents of the Diemtigen Microearthquake Sequence, Switzerland

Scale Dependence of Earthquake Rupture Prestress in Models With Enhanced Weakening: Implications for Event Statistics and Inferences of Fault Stress

Fine Structure of Microseismic Glacial Stick‐Slip

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Product

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Possible Precursory Slow‐Slip to Two M_L∼3 Mainevents of the Diemtigen Microearthquake Sequence, Switzerland

Possible Precursory Slow‐Slip to Two M_L∼3 Mainevents of the Diemtigen Microearthquake Sequence, Switzerland