Stress triggering in thrust and subduction earthquakes and stress interaction between the southern San Andreas and nearby thrust and strike‐slip faults

Lin, Jian; Stein, Ross S.

doi:10.1029/2003jb002607

Cited by 841 publications

(657 citation statements)

References 64 publications

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“…Given that the surface trace of the fault is clearly visible in the geomorphology of the mountain range to the north of Van (Figure 3) and that fault gouge was found in Quaternary sediments at the surface (Figure 4), it is very likely that the upper portion of the crust is seismogenic. The change in Coulomb stress [Lin and Stein, 2004] is predicted to have brought this upper section of the fault closer to failure (Figure 16) across the remaining unruptured fault width of 10 km, with a similar average slip of 3 m, would yield a scalar moment of 3 10 19 Nm, equivalent to a M w 6.9 earthquake. The shallower nature of such a rupture could potentially have a greater impact on Van.…”

Section: Implications For Near-surface Slip and Future Seismic Hazardmentioning

confidence: 99%

The 2011 Mw 7.1 Van (Eastern Turkey) earthquake

Elliott

Copley

Holley³

et al. 2013

JGR Solid Earth

100

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[1] We use interferometric synthetic aperture radar (InSAR), body wave seismology, satellite imagery, and field observations to constrain the fault parameters of the M w 7.1 2011 Van (Eastern Turkey) reverse-slip earthquake, in the Turkish-Iranian plateau. Distributed slip models from elastic dislocation modeling of the InSAR surface displacements from ENVISAT and COSMO-SkyMed interferograms indicate up to 9 m of reverse and oblique slip on a pair of en echelon NW 40°-54°dipping fault planes which have surface extensions projecting to just 10 km north of the city of Van. The slip remained buried and is relatively deep, with a centroid depth of 14 km, and the rupture reaching only within 8-9 km of the surface, consistent with the lack of significant ground rupture. The up-dip extension of this modeled WSW striking fault plane coincides with field observations of weak ground deformation seen on the western of the two fault segments and has a dip consistent with that seen at the surface in fault gouge exposed in Quaternary sediments. No significant coseismic slip is found in the upper 8 km of the crust above the main slip patches, except for a small region on the eastern segment potentially resulting from the M w 5.9 aftershock on the same day. We perform extensive resolution tests on the data to confirm the robustness of the observed slip deficit in the shallow crust. We resolve a steep gradient in displacement at the point where the planes of the two fault segments ends are inferred to abut at depth, possibly exerting some structural control on rupture extent.

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Section: Implications For Near-surface Slip and Future Seismic Hazardmentioning

confidence: 99%

The 2011 Mw 7.1 Van (Eastern Turkey) earthquake

Elliott

Copley

Holley³

et al. 2013

JGR Solid Earth

100

View full text Add to dashboard Cite

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“…Particularly, slip on blind thrust faults can significantly increase stress above the source fault and in other nearby zones (Lin and Stein, 2004). Driven by the coseismic stress, a fault may creep aseismically (Barbot et al, 2009).…”

Section: Mechanical Implications Of the Slip Modelsmentioning

confidence: 99%

Patterns and mechanisms of coseismic and postseismic slips of the 2011 M W 7.1 Van (Turkey) earthquake revealed by multi-platform synthetic aperture radar interferometry

Feng

Hoey

et al. 2014

Tectonophysics

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In this paper, we present several COSMO-SkyMED (CSK), Envisat ASAR and RADARSAT-2 interferograms spanning different time intervals, showing that significant postseismic signals can be observed in the first three days after the mainshock. Using observations that combine coseismic and postseismic signals is shown to significantly underestimate coseismic slip. We hence employed the CSK pair with the minimum postseismic signals to generate one conventional interferogram and one along-track interferogram for further coseismic modelling. Our best-fit coseismic slip model suggests that: (1) this event is associated with a buried NNW dipping fault with a preferable dip angle of 49º and a maximum slip of 6.5 m at a depth of 12 km; and (2) two unequal asperities can be observed, consistent with previous seismic solutions. Significant oblique aseismic slip with predominant left-lateral slip components above the coseismic rupture zone within the first 3 days after the mainshock is also revealed by a postseismic CSK interferogram, indicating that the greatest principal stress axis might have rotated due to a significant stress 1 drop during the coseismic rupture.

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“…We also assume the rake from each focal mechanism. We adopted the Coulomb 3.2 (Lin and Stein, 2004;Toda et al, 2005), assuming a frictional coefficient of 0.65. We calculate the static stress on each fault in a uniform and isotropic elastic half-space following Okada (1992).…”

Section: Calculation Of Coulomb Stress Changementioning

confidence: 99%

“…In this study, we have investigated, in detail, hypocenter distributions of several events that occurred after the M w 9.0 earthquake in order to discriminate the fault plane from the auxiliary plane of the focal mechanism. We then calculated the Coulomb stress change (Lin and Stein, 2004;Toda et al, 2005) on each fault attributable to the 2011 M w 9.0 Tohoku Earthquake to explore whether or not they were likely triggered by the M w 9.0 event.…”

Section: Introductionmentioning

confidence: 99%

Shallow inland earthquakes in NE Japan possibly triggered by the 2011 off the Pacific coast of Tohoku Earthquake

et al. 2011

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Shallow seismic activity in the crust of the overriding plate west of the source area increased significantly after the 2011 M w 9.0 Tohoku earthquake which ruptured the plate boundary to the east off northern Japan beneath the Pacific Ocean. In order to understand the cause of this distinctive change in seismicity, we have precisely relocated earthquake hypocenters for several earthquake sequences that occurred during the period March 11-April 6, 2011, following the Tohoku earthquake by the double-difference method. Hypocenter distributions were used to discriminate the fault plane from the auxiliary plane of the focal mechanisms for those earthquake sequences. We then calculated the Coulomb stress change on those fault planes caused by the 2011 M w 9 earthquake. In all cases, the estimated Coulomb stress changes at the plausible fault planes for those post-mainshock sequences are positive. The positive Coulomb stress change is mainly due to the reduction of normal stress on the fault plane of the earthquake sequences by the large, low-angle thrust fault responsible for the 2011 M w 9 earthquake. The present observations suggest that static stress transfer possibly triggered those post-mainshock earthquake sequences.

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Stress triggering in thrust and subduction earthquakes and stress interaction between the southern San Andreas and nearby thrust and strike‐slip faults

Cited by 841 publications

References 64 publications

The 2011 Mw 7.1 Van (Eastern Turkey) earthquake

The 2011 Mw 7.1 Van (Eastern Turkey) earthquake

Patterns and mechanisms of coseismic and postseismic slips of the 2011 M W 7.1 Van (Turkey) earthquake revealed by multi-platform synthetic aperture radar interferometry

Shallow inland earthquakes in NE Japan possibly triggered by the 2011 off the Pacific coast of Tohoku Earthquake

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