Your search keyword '"Northern Chile"' showing total 4 results

1. Stress Drop Variations in the Region of the 2014 MW8.1 Iquique Earthquake, Northern Chile.

Author

Folesky, Jonas, Kummerow, Jörn, and Shapiro, Serge A.

Subjects

*EARTHQUAKES, *SUBDUCTION zones, *GREEN'S functions, *WAVE analysis

Abstract

We compute stress drops from P and S phase spectra for 534 earthquakes in the source region of the 2014 MW8.1 Iquique megathrust earthquake in the northern Chilean subduction zone. An empirical Green's function based method is applied to suitable event pairs selected by template matching of eight years of continuous waveform data. We evaluate the parameters involved in the stress drop estimation, consider the effect of the local velocity structure and apply an empirical linear relation between P and S phase related geometry factors (k values). Data redundancy produced by multiple empirical Green's function and the combination of P and S phase spectra leads to a substantial reduction of uncertainty and robust stress drop estimates. The resulting stress drop values show a well‐defined log‐normal distribution with a median value of 4.36 MPa; most values range between 0.1 and 100 MPa. There is no evidence for systematic large scale lateral variations of stress drop. A detailed analysis reveals several regions of increased median stress drop, an increase with distance to the interface, but no consistent increase with depth. This suggests that fault regime and fault strength have a stronger impact on the stress drop behavior than absolute stresses. Interestingly, we find a weak time‐dependence of the median stress drop, with an increase immediately before the April 1, 2014 MW8.1 Iquique mainshock, a continuous reduction thereafter and a subsequent recovery to average values. Additionally, the data set indicates a relatively strong dependence of stress drop on magnitude which extends over the entire analyzed magnitude range. Key Points: A comprehensive stress drop distribution for the Iquique Earthquake rupture region is computed using a spectral ratio approachThe stress drops estimates reveal no large scale pattern or major trend such as a depth dependencyWe describe minor stress drop variations in greater detail and find a relatively strong scaling with moment for the entire data set [ABSTRACT FROM AUTHOR]

Published

2021

2. Probing the Northern Chile Megathrust With Seismicity: The 2014 M8.1 Iquique Earthquake Sequence.

Author

Soto, H., Sippl, C., Schurr, B., Kummerow, J., Asch, G., Tilmann, F., Comte, D., Ruiz, S., and Oncken, O.

Subjects

*EARTHQUAKES, *SEISMIC waves, *GEOPHYSICS, *VELOCITY, *EARTHQUAKE magnitude

Abstract

We used data from >100 permanent and temporary seismic stations to investigate seismicity patterns related to the 1 April 2014 M8.1 Iquique earthquake in northern Chile. Applying a multistage automatic event location procedure to the seismic data, we detected and located ~19,000 foreshocks, aftershocks, and background seismicity for 1 month preceding and 9 months following the mainshock. Foreshocks skirt around the updip limit of the mainshock asperity; aftershocks occur mainly in two belts updip and downdip of it. The updip seismicity primarily locates in a zone of transitional friction on the megathrust and can be explained by preseismic stress loading due to slow‐slip processes and afterslip driven by increased Coulomb failure stress due to the mainshock and its largest aftershock. Afterslip further south also triggered aftershocks and repeating earthquakes in several EW striking streaks. We interpret the streaks as markers of surrounding creep that could indicate a change in fault mechanics and may have structural origin, caused by fluid‐induced failure along presumed megathrust corrugations. Megathrust aftershocks terminate updip below the seaward frontal prism in the outer continental wedge that probably behaves aseismically under velocity‐strengthening conditions. The inner wedge locates further landward overlying the megathrust's seismogenic zone. Further downdip, aftershocks anticorrelate with the two major afterslip patches resolved geodetically and partially correlate with increased Coulomb failure stress, overall indicating heterogeneous frictional behavior. A region of sparse seismicity at ~40‐ to 50‐km depth is followed by the deepest plate interface aftershocks at ~55‐ to 65‐km depth, which occur in two clusters of significantly different dip. Key Points: New seismic catalog for northern Chile (18.5–22°S) contains ~19,000 events from 1 month before to 9 months after the Iquique mainshockEW striking seismicity streaks are observed in shallower portions of the megathrustAnticorrelation between aftershocks and afterslip is observed in the deeper regions of the megathrust [ABSTRACT FROM AUTHOR]

Published

2019

3. Modeling Trench Sediment‐Controlled Flow in Subduction Channels: Implications for the Topographic Evolution of the Central Andean Fore Arc.

Author

Cosentino, N. J., Morgan, J. P., and Jordan, T. E.

Subjects

*SUBDUCTION zones, *SEDIMENTATION & deposition, *LITHOSPHERE, *PLATE tectonics, *STRUCTURAL geology

Abstract

The high elevation of the onshore fore‐arc platform in northern Chile cannot be accounted for by previously proposed tectonic mechanisms such as coastal underplating and coseismic deformation, whose topographic effects are restricted to the coastal zone. Subduction channels have been recognized both in modern and fossil noncollisional convergent margins, yet their role on fore‐arc surface elevation has not been sufficiently explored. Long‐term viscoelastic flow in a strengthened, finite‐thickness subduction channel promotes coupled offshore fore‐arc subsidence and onshore fore‐arc platform uplift. We propose that the onset of protracted hyperaridity in the coastal zone of northern Chile starved the trench of sediments, inducing a rise in shear stress at the top of the subduction channel sufficient to trigger hundreds of meters of uplift of the onshore fore‐arc basin surface, most of which took place by the middle Miocene. This is consistent with latitudinal correlations between coastal precipitation, trench sediment thickness and onshore fore‐arc topography along the Chilean margin, and with available paleoclimatic and paleotopographic evidence in northern Chile. Key Points: Trench fill sediments have been proposed to influence plate interface rheology and fore‐arc elevationStrengthening the subduction channel promotes coupled long‐wavelength onshore uplift and offshore subsidence in the fore arcHyperaridity‐induced sediment starvation in the trench may explain the highly elevated onshore fore‐arc basin surface in northern Chile [ABSTRACT FROM AUTHOR]

Published

2018

4. Seismicity Structure of the Northern Chile Forearc From >100,000 Double‐Difference Relocated Hypocenters.

Author

Sippl, C., Schurr, B., Asch, G., and Kummerow, J.

Abstract

Abstract: In this study, we present high‐resolution seismicity images of the northern Chile subduction zone forearc. We used 8 years of continuous seismic waveform data from the Integrated Plate Boundary Observatory Chile network and auxiliary stations to produce an extensive earthquake catalog containing 101,601 double‐difference relocated earthquake hypocenters using automatic event detection and phase picking routines. The minimum magnitude of retrieved events is <2, and the catalog is estimated to be complete at magnitudes above ∼2.8. Intraslab seismicity makes up the majority of detected earthquakes. Where the seismogenic zone of the megathrust is active, a clear separation of seismicity into three distinct planes can be observed. The uppermost plane corresponds to the plate interface, which is observed to terminate downdip at a depth of 50–55 km. The other two planes, located ∼7 and ∼26 km below the slab surface, dip at a constant angle of about 20° until they are absorbed by a 25 km thick highly active cluster of intermediate‐depth seismicity at depths of 80–120 km. Downdip of this cluster, the slab steepens and lower plate seismicity is considerably sparser, even absent in the northern part of the study area. Upper plate seismicity is also considerable, with a segment between 21 and 21.6°S standing out for featuring pervasive activity occurring all the way down to the plate interface. Here the seismicity resembles a wedge in west‐east profile view and occurs where the upper plate crust is coldest based on thermal models. [ABSTRACT FROM AUTHOR]

Published

2018