Quantifying the remote triggering capabilities of large earthquakes using data from the ANZA Seismic Network catalog (southern California)

Kane, D. L.; Kilb, Debi; Berg, Arthur; Martynov, V. G.

doi:10.1029/2006jb004714

Cited by 17 publications

(18 citation statements)

References 41 publications

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“…All distant earthquakes identified as triggers can be seen in Tables S4 and S5. We did not find any instances of distant earthquakes triggering microearthquakes near Parkfield, an observation similar to Kane et al [] who investigated remote triggering along the San Jacinto Fault in southern California. Figure shows a comparison of the triggered behaviors caused by the 11 March 2011 M w 9.0 Tohoku‐Oki earthquake, as recorded in Parkfield ( σ = 10 kPa), Long Valley ( σ = 10 kPa), Coso ( σ = 7 kPa), and Geysers ( σ = 9 kPa).…”

Section: Parkfield Segment Observationsmentioning

confidence: 98%

Dynamic triggering of microearthquakes in three geothermal/volcanic regions of California

Aiken

Peng

2014

JGR Solid Earth

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Geothermal/volcanic regions are most susceptible to local earthquake triggering by regional and remote earthquakes. Transient stresses caused by surface waves of these earthquakes can activate critically stressed faults. Though earthquakes can be triggered in geothermal/volcanic regions, it is less understood how these regions differ in their triggering responses to distant earthquakes. We conduct a systematic survey of local earthquakes triggered by distant earthquakes in three geothermal/volcanic regions of California: Long Valley Caldera, Coso Geothermal Field, and Geysers Geothermal Field. We examine waveforms of distant earthquakes with magnitudes ≥ 5.5 occurring between 2000 and 2012 and compute β statistics to confirm the significance of our findings. We find that Long Valley, Coso, and Geysers vary in triggering frequency-2.0%, 3.8%, and 6.8% in the 12 year period, respectively-and when compared to the triggering of deep tectonic tremors along the Parkfield-Cholame section of San Andreas Fault (9.2% in the 12 year period). Stress triggering thresholds vary among the regions with Long Valley having the highest of~5 kPa and 1 kPa for the other regions. Because dynamic stresses from distant earthquakes are similar in these three regions, the varying triggering behavior likely reflects faults having a tendency to be at or near failure. This is compatible with Geysers having a higher a value in the Gutenberg-Richter relationship and higher geothermal productivity than the other two regions. The observation of more frequent triggering of tremor than microearthquakes is consistent with recent laboratory studies on increasing triggerability with lower effective stress.

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Section: Parkfield Segment Observationsmentioning

confidence: 98%

Dynamic triggering of microearthquakes in three geothermal/volcanic regions of California

Aiken

Peng

2014

JGR Solid Earth

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“…Others have required events at any distance to occur within a short time after the passage of seismic waves. For example, Moran et al (2004) used a 1 h limit and Kane et al (2007) a 2 day window to examine triggered earthquakes. Selva et al (2004) used more intricate space-time constraints corresponding to the evolution of stress in a model system.…”

Section: Triggered Eruption Of Mud Volcanoesmentioning

confidence: 99%

“…Brodsky and Prejean (2005) found that long-period (>30 s) waves are more effective at triggering earthquakes in the magmatically active Long Valley Caldera. However, Kane et al (2007) found that if there is a frequency dependence for triggered earthquakes in Southern California, the most effective frequencies must be >2 Hz.…”

Section: Frequency Dependence Of Observationsmentioning

confidence: 99%

Earthquake triggering of mud volcanoes

Manga

Brumm

Rudolph

2009

Marine and Petroleum Geology

157

134

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“…Aftershock sequences are certainly the most easily observed pieces of evidence of such interaction. In spite of that clear empirical evidence, less clear and still under discussion are the physical mechanisms involved [ Felzer and Brodsky , 2006; Kane et al , 2007; Hill , 2008; Velasco et al , 2008; Richards‐Dinger et al , 2010]. In general, each earthquake can trigger (or inhibit) future earthquakes through different physical processes, such as dynamical triggering, coseismic and postseismic perturbations [e.g., Chéry et al , 2001; Marzocchi et al , 2003; Freed , 2005], pore fluids effects [ Keller and Loaiciga , 1993; Miller et al , 2004; Lombardi et al , 2010], etc., but the relative importance of each process, and how far in space and time such interactions may act, are still debated.…”

Section: Introductionmentioning

confidence: 99%

Stochastic models for earthquake triggering of volcanic eruptions

Bebbington

Marzocchi

2011

J. Geophys. Res.

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[1] Many accounts, anecdotal and statistical, have noted a causal effect on volcanic eruptions from large, not too distant, earthquakes. Physical mechanisms have been proposed that explain how small static stress changes, or larger transient dynamic stress changes, can have observable effects on a volcano. While only ∼0.4% of eruptions appear to be directly triggered within a few days of an earthquake, these physical mechanisms also imply the possibility of delayed triggering. In the few regional studies conducted, data issues (selection bias and scarcity, inhomogeneity, and cleaning of data) have tended to obscure any clear signal. Using a perturbation technique, we first show that the Indonesian volcanic region possesses no statistically significant coupling for the region as a whole. We then augment a number of point process models for eruption onsets by a time-, distance-, and earthquake magnitude-dependent triggering term and apply this to the individual volcanoes. This method weighs both positive and negative (i.e., absence of eruptions following an earthquake) evidence of triggering. Of 35 volcanoes with at least three eruptions in the study region, seven (Marapi, Talang, Krakatau, Slamet, Ebulobo, Lewotobi, and Ruang) show statistical evidence of triggering over varying temporal and spatial scales, but only after the internal state of the volcano is accounted for. This confirms that triggering is fundamentally a property of the internal magma plumbing of the volcano in question and that any earthquake can potentially "advance the clock" toward a future eruption. This is further supported by the absence of any dependence on triggering of the eruption size.

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Quantifying the remote triggering capabilities of large earthquakes using data from the ANZA Seismic Network catalog (southern California)

Cited by 17 publications

References 41 publications

Dynamic triggering of microearthquakes in three geothermal/volcanic regions of California

Dynamic triggering of microearthquakes in three geothermal/volcanic regions of California

Earthquake triggering of mud volcanoes

Stochastic models for earthquake triggering of volcanic eruptions

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