Post-seismic motion following the 1997 Manyi (Tibet) earthquake: InSAR observations and modelling

Ryder, Isabelle; Parsons, B.; Wright, Tim; Funning, Gareth J.

doi:10.1111/j.1365-246x.2006.03312.x

Cited by 154 publications

(197 citation statements)

References 47 publications

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“…Similar inferences have also recently been made on the basis of decadal observations of postseismic data alone (e.g., Ryder et al, 2007;Hearn et al, 2009). These results suggest that, in contrast to the classical single relaxation time model, variations in surface velocities throughout the earthquake cycle may be subtle and challenging to identify in the presence of multiple faults and observational noise.…”

Section: Resultssupporting

confidence: 59%

“…However, steady-state CEH models are inconsistent with observations of spatially broad (> 100 km), time-variable, postseismic deformation following large earthquakes (e.g., Nur and Mavko, 1974;Hetland and Hager, 2003;Pollitz, 2003;Freed and Bürgmann, 2004;Freed et al, 2006;Ryder et al, 2007). Models for time-dependent earthquake-cycle deformation have generally focused on either the diffuse deformation of a linear viscoelastic subseismogenic layer (e.g., Thatcher, 1983;Savage, 1990;Dixon et al, 2002Dixon et al, , 2003Ergintav et al, 2002;Segall, 2002;Hilley et al, 2005, Motagh et al, 2007 or localized shear on a down-dip extension of the coseismic fault zone (e.g., Marone et al, 1991;Bürgmann et al, 2002), whereas recently more postseismic models have incorporated both (e.g., Freed et al, 2006;Johnson et al, 2009).…”

Section: Introductionmentioning

confidence: 91%

“…For example, in the context of earthquake-cycle models assuming a single relaxation timescale, analysis of postseismic deformation suggested upper mantle effective viscosities of, or less than, 10 18 Pa s (e.g., Pollitz et al, 2001) whereas late in the earthquake-cycle deformation has been interpreted as consistent with viscosities of a subseismogenic layer exceeding 10 19 Pa s (e.g., Hilley et al, 2005;Meade and Hager, 2005). More recently, the analysis of postseismic deformation signals has led to the suggestion that single relaxation timescale models may not be sufficient to describe behavior within the postseismic regime alone (e.g., Pollitz et al, 2001;Pollitz, 2003Pollitz, , 2005Freed and Bürgmann, 2004;Ryder et al, 2007;Hearn et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Inference of Multiple Earthquake-Cycle Relaxation Timescales from Irregular Geodetic Sampling of Interseismic Deformation

Meade

Klinger

Hetland

2013

Bulletin of the Seismological Society of America

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Characterizing surface deformation throughout a full earthquake cycle is a challenge due to the lack of high-resolution geodetic observations of duration comparable to that of characteristic earthquake recurrence intervals (250-10,000 years). Here we approach this problem by comparing long-term geologic slip rates with geodetically derived fault slip rates by sampling only a short fraction (0.001%-0.1%) of a complete earthquake cycle along 15 continental strike-slip faults. Geodetic observations provide snapshots of surface deformation from different times through the earthquake cycle. The timing of the last earthquake on many of these faults is poorly known, and may vary greatly from fault to fault. Assuming that the underlying mechanics of the seismic cycle are similar for all faults, geodetic observations from different faults may be interpreted as samples over a significantly larger fraction of the earthquake cycle than could be obtained from the geodetic record along any one fault alone. As an ensemble, we find that geologically and geodetically inferred slip rates agree well with a linear relation of 0:94 0:09. To simultaneously explain both the ensemble agreement between geologic and geodetic slip-rate estimates with observations of rapid postseismic deformation, we consider the predictions from simple two-layer earthquake-cycle models with both Maxwell and Burgers viscoelastic rheologies. We find that a two-layer Burgers model, with two relaxation timescales, is consistent with observations of deformation throughout the earthquake cycle, whereas the widely used two-layer Maxwell model with a single relaxation timescale, is not, suggesting that the earthquake cycle is effectively characterized by a largely stressrecoverable rapid postseismic stage and a much more slowly varying interseismic stage.

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Section: Resultssupporting

confidence: 59%

Section: Introductionmentioning

confidence: 91%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Inference of Multiple Earthquake-Cycle Relaxation Timescales from Irregular Geodetic Sampling of Interseismic Deformation

Meade

Klinger

Hetland

2013

Bulletin of the Seismological Society of America

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“…Wright et al [21] werethe first to use InSAR for studying the interseismic deformation. InSAR has been proven to be a important tool in researching the seismic cycle deformation after many successful applications in coseismic [20], postseismic [29] and interseismic [16,21,22,27,28] deformation. Walters et al [22] improved Wright and coworkers' results [21] by using SAR data from two different look directions, in their paper, they stated that the uncertainties in slip rate and locking depth are reduced up to 60% which is a huge improvement.…”

Section: Interseismic Rate Map From Insar Time Seriesmentioning

confidence: 99%

Interseismic Deformation of the Altyn Tagh Fault Determined by Interferometric Synthetic Aperture Radar (InSAR) Measurements

Zhu

Wen

et al. 2016

Remote Sensing

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Abstract:The Altyn Tagh Fault (ATF) is one of the major left-lateral strike-slip faults in the northeastern area of the Tibetan Plateau. In this study, the interseismic deformation across the ATF at 85˝E was measured using 216 interferograms from 33 ENVISAT advanced synthetic aperture radar images on a descending track acquired from 2003 to 2010, and 66 interferograms from 15 advanced synthetic aperture radar images on an ascending track acquired from 2005 to 2010. To retrieve the pattern of interseismic strain accumulation, a global atmospheric model (ERA-Interim) provided by the European Center for Medium Range Weather Forecast and a global network orbital correction approach were applied to remove atmospheric effects and the long-wavelength orbital errors in the interferograms. Then, the interferometric synthetic aperture radar (InSAR) time series with atmospheric estimation model was used to obtain a deformation rate map for the ATF. Based on the InSAR velocity map, the regional strain rates field was calculated for the first time using the multi-scale wavelet method. The strain accumulation is strongly focused on the ATF with the maximum strain rate of 12.4ˆ10´8/year. We also show that high-resolution 2-D strain rates field can be calculated from InSAR alone, even without GPS data. Using a simple half-space elastic screw dislocation model, the slip-rate and locking depth were estimated with both ascending and descending surface velocity measurements. The joint inversion results are consistent with a left-lateral slip rate of 8.0˘0.7 mm/year on the ATF and a locking depth of 14.5˘3 km, which is in agreement with previous results from GPS surveys and ERS InSAR results. Our results support the dynamic models of Asian deformation requiring low fault slip rate.

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“…Several physical mechanisms can contribute to postseismic deformation (Fialko, 2004;Ryder et al, 2007), including afterslip, poroelastic rebound and viscoelastic relaxation. Following Peltzer et al's approach (1998) different Poisson's ratios were used for undrained and drained upper crust conditions to simulate potential surface deformation caused by poroelastic relaxation .…”

Section: Postseismic Modellingmentioning

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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Post-seismic motion following the 1997 Manyi (Tibet) earthquake: InSAR observations and modelling

Cited by 154 publications

References 47 publications

Inference of Multiple Earthquake-Cycle Relaxation Timescales from Irregular Geodetic Sampling of Interseismic Deformation

Inference of Multiple Earthquake-Cycle Relaxation Timescales from Irregular Geodetic Sampling of Interseismic Deformation

Interseismic Deformation of the Altyn Tagh Fault Determined by Interferometric Synthetic Aperture Radar (InSAR) Measurements

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

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