The M<sub>W</sub>=8.1 Antofagasta (North Chile) Earthquake of July 30, 1995: First results from teleseismic and geodetic data

Ruegg, Jean; Campos, Jaime; Armijo, Rolando; Barrientos, Sergio; Briole, Pierre; Thiele, Ricardo; Arancibia, M.; Cañuta, J.; Duquesnoy, Thierry; Chang, M.; Lazo, D.; Lyon‐Caen, H.; Ortlieb, Luc; Rossignol, J. C.; Serrurier, L.

doi:10.1029/96gl01026

Cited by 106 publications

(108 citation statements)

References 10 publications

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“…The M W 8.4 Arequipa earthquake in 2001 could therefore have introduced a velocity change of 1.2 per cent leading to the linear trend in the velocity changes that we observe during the study period. As the rupture duration of the Antofagasta earthquake was shorter (60 s; Ruegg et al 1996) compared to the one of the Arequipa earthquake but with a similar maximal shaking (estimated by extrapolation), we conclude that the 1995 earthquake seems less plausible to induce a velocity change of 2.5 per cent which would be necessary to cause the linear trend. Considering that the effects of the different earthquakes are superimposed it seems very likely that the linear trend, which was empirically introduced to fit the data, also consistently results from our model.…”

Section: Linear Trendmentioning

confidence: 56%

Field observations of seismic velocity changes caused by shaking-induced damage and healing due to mesoscopic nonlinearity

et al. 2016

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Section: Linear Trendmentioning

confidence: 56%

Field observations of seismic velocity changes caused by shaking-induced damage and healing due to mesoscopic nonlinearity

et al. 2016

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“…The rupture length and location for recent strong events were taken from Barrientos & Ward (1990) for the M9.6 1960 Valdivia earthquake, Delouis et al (1997) for the M7.6 1987 earthquake near Antofagasta, Ruegg et al (1996) for the M8.0 1995 Antofagasta earthquake, Pritchard & Simons (2006) for the M9.6 1960 Valdivia earthquake, Chlieh et al (2011) for the M8.4 2001 Arequipa earthquake, the rupture plane of which extends well into our area of investigation, Schurr et al (2014) for the M7.9 2007 Tocopilla earthquake, Yue et al (2014) for the M8.8 2010 Maule earthquake, Geersen et al (2015) and Schurr et al (2014) for the M8.1 2014 Iquique earthquake, and Tilmann et al (2016) for the M8.2 2015 Illapel earthquake. In the case that the rupture length is not constrained by observations, we estimate rupture lengths from the scaling relation of Blaser et al (2010) for dip-slip inter-plate earthquakes.…”

Section: Data Preparationmentioning

confidence: 99%

Testing stress shadowing effects at the South American subduction zone

Roth¹,

Dahm²,

Hainzl³

2017

Geophysical Journal International

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S U M M A R YThe seismic gap hypothesis assumes that a characteristic earthquake is followed by a long period with a reduced occurrence probability for the next large event on the same fault segment, as a consequence of the induced stress shadow. The gap model is commonly accepted by geologists and is often used for time-dependent seismic hazard estimations. However, systematic and rigorous tests to verify the seismic gap model have often failed so far, which might be partially related to limited data and too tight model assumptions. In this study, we relax the assumption of a characteristic size and location of repeating earthquakes and analyse one of the best available data sets, namely the historical record of major earthquakes along a 3000 km long linear segment of the South American subduction zone. To test whether a stress shadow effect is observable, we compiled a comprehensive catalogue of mega-thrust earthquakes along this plate boundary from 1520 to 2015 containing 174 earthquakes with M w > 6.5. In our new testing approach, we analyse the time span between an earthquake and the last event that ruptured the epicentre location, where we consider the impact of the uncertainties of epicentres and rupture extensions. Assuming uniform boundary conditions along the trench, we compare the distribution of these recurrence times with simple recurrence models. We find that the distribution is in all cases almost exponentially distributed corresponding to a random (Poissonian) process; despite some tendencies for clustering of the M w ≥ 7 events and a weak quasi-periodicity of the M w ≥ 8 earthquakes, respectively. To verify whether the absence of a clear stress shadow signal is related to physical assumptions or data uncertainties, we perform simulations of a physics-based stochastic earthquake model considering rate and state-dependent earthquake nucleation, which are adapted to the observations with regard to the number of events, spatial extend, size distribution and involved uncertainties. Our simulations show that the catalogue uncertainties lead to a significant blurring of the theoretically peaked distribution, but the distribution would be still distinguishable from the observed one for M w ≥ 7 events. However, considering the stress transfer to adjacent fault segments and heterogeneous instead of constant stress drop within the rupture zone can explain the observed recurrence time distribution. We conclude that simplified recurrence models, ignoring the complexity of the underlying physical process, cannot be applied for forecasting the M w ≥ 7 earthquake occurrence at this plate boundary.

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“…Rupture plane location of the M W = 8.0 Antofagasta, Chile, earthquake after Ruegg et al [1996]. The fault extends 180 km along strike and 80 km in the dip direction and appears at the interface between oceanic and Andes continental crust inside the seismogenic zone.…”

Section: The Modelmentioning

confidence: 99%

A model of deep crustal fluid flow following the M_w = 8.0 Antofagasta, Chile, earthquake

2004

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[1] We develop a model to test the hypothesis that a high fluid pressure pulse and subsequent fluid flow caused a spatially extensive increase in the V P /V S ratio following the M w = 8.0 Antofagasta, Chile, subduction zone earthquake. The postseismic anomaly appeared within a 50-day period inside the forearc region of the Andes continental crust. We model this anomaly with a poroelastic medium that combines the fluid flow response to mean stress changes from slip along a dislocation plane, with a pore pressure pulse initiated by the coseismic rupturing of a seal separating hydrostatic-lithostatic fluid pressure conditions in the hanging walls and footwalls of the subduction zone, respectively. Variations in seismic velocity due to porosity and pore pressure changes are calculated using Gassmann's formula and the empirical law of critical porosity. We show that the slip-induced perturbation of the mean stress field is insufficient to explain the anomaly, but the release of lithostatic pressurized fluid trapped below the rupture plane (within the oceanic crust) can explain the transient changes in seismic velocities. Our preferred model requires a very large intrinsic permeability of around 1 Â 10 À13 m 2 , suggesting a mechanism of a high-amplitude pressure pulse propagating through a highly permeable fracture system of the lower continental crust.

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The M_W=8.1 Antofagasta (North Chile) Earthquake of July 30, 1995: First results from teleseismic and geodetic data

Cited by 106 publications

References 10 publications

Field observations of seismic velocity changes caused by shaking-induced damage and healing due to mesoscopic nonlinearity

Field observations of seismic velocity changes caused by shaking-induced damage and healing due to mesoscopic nonlinearity

Testing stress shadowing effects at the South American subduction zone

A model of deep crustal fluid flow following the M_w = 8.0 Antofagasta, Chile, earthquake

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The MW=8.1 Antofagasta (North Chile) Earthquake of July 30, 1995: First results from teleseismic and geodetic data

Cited by 106 publications

References 10 publications

Field observations of seismic velocity changes caused by shaking-induced damage and healing due to mesoscopic nonlinearity

Field observations of seismic velocity changes caused by shaking-induced damage and healing due to mesoscopic nonlinearity

Testing stress shadowing effects at the South American subduction zone

A model of deep crustal fluid flow following the Mw = 8.0 Antofagasta, Chile, earthquake

Contact Info

Product

Resources

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The M_W=8.1 Antofagasta (North Chile) Earthquake of July 30, 1995: First results from teleseismic and geodetic data

A model of deep crustal fluid flow following the M_w = 8.0 Antofagasta, Chile, earthquake