Evidence for Synchronization in the Global Earthquake Catalog

Bendick, Rebecca; Mencin, D.

doi:10.1029/2020gl087129

Cited by 6 publications

(2 citation statements)

References 42 publications

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“…Additionally, far eld triggering of seismicity (e.g. Freed, 2005), and evidence for global synchronization of earthquakes (Bendick & Bilham, 2017;Bendick & Mencin, 2020) both cast doubt on the Poisson process hypothesis for large scale systems.…”

Section: Introductionmentioning

confidence: 99%

A Comparative Analysis of Four Commonly Implemented Declustering Algorithms

Perry

Bendick

2023

Preprint

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Declustering of earthquake catalogs, that is determining dependent and independent events in an earthquake sequence, is a common feature of many seismological studies. While many different declustering algorithms exist, each has different performance and sensitivity characteristics. Here, we conduct a comparative analysis of the four most commonly used declustering algorithms: Garnder and Knopoff (1975), Reasenberg (1985), Zhuang et al. (2002), and Zaliapin and Ben-Zion (2008) in four different tectonic settings. Overall, we find that the Zaliapin and Ben-Zion (2008) algorithm effectively removes aftershock sequences, while simultaneously retaining the most information (i.e. the most events) in the output catalog and not significantly modifying statistical characteristics (i.e. the Gutenberg Richter b-value). Both Gardner and Knopoff (1975) and Zhuang et al. (2002) also effectively remove aftershock sequences, though they remove significantly more events than the other algorithms. By contrast, Reasenberg (1985) only effectively removed aftershocks in one of the test regions.

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Section: Introductionmentioning

confidence: 99%

A Comparative Analysis of Four Commonly Implemented Declustering Algorithms

Perry

Bendick

2023

Preprint

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“…Love and Shida numbers) due to its local temperature and geochemistry. These modulations act through two different mechanisms on the outer layers of the Solid Earth: the brittle and outermost part of the crust is elastically affected by tidal waves, which induce a stress variation in rocks that, depending on the local geodynamics, promotes or, on the contrary, can prevent the achievement of the critical breaking point, so that it plays a statistically significant role in fault activation [14][15][16], while solid tides actively modulate plate motion at low frequencies over geological periods [17,18] due to a heterogeneous dissipation of the tidal torque at the LVZ level.…”

Section: Introductionmentioning

confidence: 99%

Different Fault Response to Stress during the Seismic Cycle

2021

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Seismic prediction was considered impossible, however, there are no reasons in theoretical physics that explicitly prevent this possibility. Therefore, it is quite likely that prediction is made stubbornly complicated by practical difficulties such as the quality of catalogs and data analysis. Earthquakes are sometimes forewarned by precursors, and other times they come unexpectedly; moreover, since no unique mechanism for nucleation was proven to exist, it is unlikely that single classical precursors (e.g., increasing seismicity, geochemical anomalies, geoelectric potentials) may ever be effective in predicting impending earthquakes. For this reason, understanding the physics driving the evolution of fault systems is a crucial task to fine-tune seismic prediction methods and for the mitigation of seismic risk. In this work, an innovative idea is inspected to establish the proximity to the critical breaking point. It is based on the mechanical response of faults to tidal perturbations, which is observed to change during the “seismic cycle”. This technique allows to identify different seismic patterns marking the fingerprints of progressive crustal weakening. Destabilization seems to arise from two different possible mechanisms compatible with the so called preslip patch, cascade models and with seismic quiescence. The first is featured by a decreasing susceptibility to stress perturbation, anomalous geodetic deformation, and seismic activity, while on the other hand, the second shows seismic quiescence and increasing responsiveness. The novelty of this article consists in highlighting not only the variations in responsiveness of faults to stress while reaching the critical point, but also how seismic occurrence changes over time as a function of instability. Temporal swings of correlation between tides and nucleated seismic energy reveal a complex mechanism for modulation of energy dissipation driven by stress variations, above all in the upper brittle crust. Some case studies taken from recent Greek seismicity are investigated.

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A comparative analysis of five commonly implemented declustering algorithms

Perry,

Bendick

2024

J Seismol

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Evidence for Synchronization in the Global Earthquake Catalog

Cited by 6 publications

References 42 publications

A Comparative Analysis of Four Commonly Implemented Declustering Algorithms

A Comparative Analysis of Four Commonly Implemented Declustering Algorithms

Different Fault Response to Stress during the Seismic Cycle

A comparative analysis of five commonly implemented declustering algorithms

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