Spatial and temporal variations in creep rate along the El Pilar fault at the Caribbean‐South American plate boundary (Venezuela), from InSAR

Pousse‐Beltran, Léa; Pathier, Erwan; Jouanne, François; Vassallo, Riccardo; Reinoza, Carlos; Audemard, Franck; Doin, Marie‐Pierre; Volat, Matthieu

doi:10.1002/2016jb013121

Cited by 30 publications

(22 citation statements)

References 99 publications

(218 reference statements)

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“…The maximum amplitude (~10 mm in our case, whereas it was~20 mm along the Ismetpasa section) and duration of these shallow bursts (~1 month) are similar. The growing number of evidence for such creep bursts along the North Anatolian Fault, as also suggested by long time series of creepmeter measurements (Altay & Sav, 1991;Bilham et al, 2016), and along other major strike-slip faults worldwide (De Michele et al, 2011;Jolivet, Simons, et al, 2015;Khoshmanesh & Shirzaei, 2018;Pousse-Beltram et al, 2016), suggest that continuously decaying afterslip or steady interseismic creep may not be the rule for creep behavior. New mechanical models are required to account for coupling temporal variations at shallow depth and recurrent creep bursts triggering.…”

Section: High Temporal Resolution Insar Data Reveal Burst-like Behavimentioning

confidence: 99%

“…A recent review by Harris (2017) discussed the earthquake potential of shallow creeping continental faults using worldwide data. Reported cases include the Hayward fault (Savage & Lisowski, 1993;Schmidt et al, 2005), the Supersitition Hills fault (Bilham, 1989;Wei et al, 2009), and the Central San Andreas Fault in California (De Michele et al, 2011, Jolivet, Candela, et al, 2015, Khoshmanesh & Shirzaei, 2018, the Longitudinal Valley fault in Taiwan (Champenois et al, 2012;Thomas et al, 2014), the Ismetpasa segment of North Anatolian Fault in Turkey (Ambraseys, 1970;Bilham et al, 2016;Cakir et al, 2005;Cetin et al, 2014;Kaneko et al, 2013;Rousset et al, 2016), the Izmit and Marmara segment of the North Anatolian Fault (Cakir et al, 2012;Ergintav et al, 2014;Hussain et al, 2016), the Haiyuan fault in China (Jolivet et al, 2012, Jolivet, Simons, et al, 2015, the El-Pilar fault in Venezuela (Jouanne et al, 2011, Pousse-Beltram et al, 2016, and the Chaman fault in Pakistan (Barnhart, 2017;Fattahi & Amelung, 2016). These studies show that the spatial patterns (rate and rate-change distribution along strike and with depth) vary significantly.…”

Section: Fault Creep and Seismic Potentialmentioning

confidence: 99%

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Shallow Creep Along the 1999 Izmit Earthquake Rupture (Turkey) From GPS and High Temporal Resolution Interferometric Synthetic Aperture Radar Data (2011–2017)

et al. 2019

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Characterizing the spatiotemporal evolution of creep is essential to constrain fault slip budget and understand creep mechanism. Studies based on interferometric synthetic aperture radar and Global Positioning System (GPS) satellite observations until 2012 have shown that the central segment of the 17 August 1999 Mw 7.4 Izmit earthquake on the North Anatolian Fault began slipping aseismically following the event. In the present study, we combine new interferometric synthetic aperture radar time series, based on TerraSAR‐X and Sentinel 1A/B radar images acquired over the period 2011–2017, with near‐field GPS measurement campaigns performed every 6 months from 2014 to 2016. The mean velocity fields reveal that creep on the central segment of the 1999 Izmit fault rupture continues to decay, more than 19 years after the earthquake, in overall agreement with models of postseismic afterslip decaying logarithmically with time for a long period of time. Along the fault section that experienced supershear velocity rupture during the Izmit earthquake creep continues with a rate up to ~ 8 mm/year. A significant transient accelerating creep is detected in December 2016 on the Sentinel‐1 time series, near the maximum creep rate location, associated with a total surface slip of 10 mm released in 1 month only. Additional analyses of the vertical velocity fields show a persistent subsidence on the hanging wall block of the Golcuk normal fault that also ruptured during the Izmit earthquake. Our results demonstrate that afterslip processes along the North Anatolian Fault east‐southeast of Istanbul are more complex than previously proposed as they vary spatiotemporally along the fault.

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Section: High Temporal Resolution Insar Data Reveal Burst-like Behavimentioning

confidence: 99%

Section: Fault Creep and Seismic Potentialmentioning

confidence: 99%

Shallow Creep Along the 1999 Izmit Earthquake Rupture (Turkey) From GPS and High Temporal Resolution Interferometric Synthetic Aperture Radar Data (2011–2017)

et al. 2019

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“…Along any fault network where regional‐scale, dense, and continuous geodetic data sets have been gathered, we have been able to observe slow slip (Figure ). The advent of continuously operating GPS networks and high‐resolution InSAR time series provoked a series of slow slip discoveries across multiple subduction zones and major continental fault networks (e.g., Cavalié et al, ; Duquesnoy et al, ; Pousse Beltran et al, ; Wallace et al, ). We have observed slow slip to exhibit a range of temporal behaviors, including periodic oscillations or episodic transients, along all kinds of plate boundaries, whether convergent, divergent, or transform and even within volcanic contexts (Cervelli et al, ; Doubre & Peltzer, ; Jolivet et al, ; Rogers & Dragert, ).…”

Section: Slow Slip Is Ubiquitousmentioning

confidence: 99%

The Transient and Intermittent Nature of Slow Slip

Jolivet

Frank

2020

AGU Advances

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To first order, faults are locked while stress builds up to a devastating earthquake. However, we know that faults also slip slowly. After decades of geophysical observation, slow slip is now recognized as part of a continuum of transient deformation ranging from the dynamic propagation of seismic rupture to aseismic events over a wide range of durations and sizes. A growing body of evidence suggests that large‐scale slow slip events can be decomposed into a multitude of smaller, temporally clustered events. Slow slip is more frequent and more dynamic than is suggested by conceptual models of rate‐strengthening, stable slip.

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“…Moreover, assuming a nearly-constant and continuous creep in time, one can estimate the slip deficit and determine the fault's seismic potential (e.g., Jolivet, Simons, et al, 2015;Rolandone et al, 2008). Timedependent observation of the kinematics of creeping segments, on the other hand, indicates that creep evolves as a series of transient accelerating events during interseismic period (e.g., Beltran et al, 2016;Jolivet, Candela, et al, 2015;Lockner et al, 2011;Nadeau & McEvilly, 2004;Turner et al, 2015). These transient events, known as slow slip events, can load surrounding locked patches and possibly trigger seismic events (e.g., Kato et al, 2012;Radiguet et al, 2016;Uchida et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Multiscale Dynamics of Aseismic Slip on Central San Andreas Fault

Khoshmanesh

Shirzaei

2018

Geophysical Research Letters

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Understanding the evolution of aseismic slip enables constraining the fault's seismic budget and provides insight into dynamics of creep. Inverting the time series of surface deformation measured along the Central San Andreas Fault obtained from interferometric synthetic aperture radar in combination with measurements of repeating earthquakes, we constrain the spatiotemporal distribution of creep during 1992–2010. We identify a new class of intermediate‐term creep rate variations that evolve over decadal scale, releasing stress on the accelerating zone and loading adjacent decelerating patches. We further show that in short‐term (<2 year period), creep avalanches, that is, isolated clusters of accelerated aseismic slip with velocities exceeding the long‐term rate, govern the dynamics of creep. The statistical properties of these avalanches suggest existence of elevated pore pressure in the fault zone, consistent with laboratory experiments.

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Spatial and temporal variations in creep rate along the El Pilar fault at the Caribbean‐South American plate boundary (Venezuela), from InSAR

Cited by 30 publications

References 99 publications

Shallow Creep Along the 1999 Izmit Earthquake Rupture (Turkey) From GPS and High Temporal Resolution Interferometric Synthetic Aperture Radar Data (2011–2017)

Shallow Creep Along the 1999 Izmit Earthquake Rupture (Turkey) From GPS and High Temporal Resolution Interferometric Synthetic Aperture Radar Data (2011–2017)

The Transient and Intermittent Nature of Slow Slip

Multiscale Dynamics of Aseismic Slip on Central San Andreas Fault

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