Spatiotemporal evolution of seismic and aseismic slip on the Longitudinal Valley Fault, Taiwan

Thomas, Marion Y.; Avouac, Jean Philippe; Champenois, Johann; Lee, Jian Cheng; Kuo, Long-Chen

doi:10.1002/2013jb010603

Cited by 90 publications

(155 citation statements)

References 91 publications

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“…Since we do not have sufficient data to perform a nonlinear source inversion, we search for a source compatible with the LVF or with the CRF (see section for details). We adopt the fault geometry defined by M. Y. Thomas et al () for the LVF, that is, a dip angle decreasing gradually from about 60° at 0–14 km to about 45° at 14–22 km and to 30° at 22–27 km. The fault strike is set to 30°NE and the geologic rake to 60° which corresponds to the slip vector direction estimated at the surface in the Ruisui region (around latitude 23°26 ′ ; Peyret et al, ).…”

Section: Source Characterizationsupporting

confidence: 64%

“…The fault also displays aseismic slip at seismogenic depths, as evidenced by moderate to large frictional afterslip (Canitano, Godano, et al, ; Y. J. Hsu et al, ). Based on the analysis of 18 years of geodetic data (1992–2010) for the LVF which includes the large postseismic slip following the 2003 Chengkung earthquake (e.g., Y. J. Hsu et al, ), M. Y. Thomas et al () inferred that a major fraction (>80%) of the long‐term slip budget on the southern section of the LVF is the result of aseismic slip. The CRF, located on the western side of the valley, is a high‐angle reverse west‐dipping structure (Shyu et al, ), also capable of producing large earthquakes such as the October 2013 M w 6.2 Ruisui event (Canitano et al, , ).…”

Section: Slow Rupture Observation In Eastern Taiwanmentioning

confidence: 99%

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Testing the Influence of Static and Dynamic Stress Perturbations On the Occurrence of a Shallow, Slow Slip Event in Eastern Taiwan

et al. 2019

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We report the first evidence for the detection of a slow slip event in the Longitudinal Valley, in eastern Taiwan. The slow event, which lasted about 3.5 days, has been detected by borehole strainmeters. It occurred at shallow depths (about 2 to 4 km), either on the Longitudinal Valley Fault or on the Central Range Fault. Here we investigate whether the event occurrence was influenced by transient and periodic stress perturbations, in particular by the June 2013 Mw 6.2 Nantou earthquake, which occurred about 60 km away and 6 days prior to the event. Modeled changes in Coulomb stress in the direction parallel to the geologic slip vector on the fault planes show negative static stress changes (approximately −1.5 to −1 kPa), while maximum dynamic stress changes generated by the surface waves are ranging from 5.5 to 14.5 kPa. We also observe that the slow event initiated during a maximum of Earth and ocean tidal Coulomb stress changes (about 0.8 to 1.5 kPa). Dynamic and static stress perturbations represent a few percents to tens of percents of the stress buildup through the slow rupture cycle. However, the absence of recurrent events during the 12 years of strain monitoring (2006 to 2018) prevents to estimate the recurrence interval of the slow event, which limits our ability to further interpret the link between the rupture and the perturbations. Finally, there is no large and unique load transient at the time of the initiation, therefore this single event may have likely occurred spontaneously.

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Section: Source Characterizationsupporting

confidence: 64%

Section: Slow Rupture Observation In Eastern Taiwanmentioning

confidence: 99%

Testing the Influence of Static and Dynamic Stress Perturbations On the Occurrence of a Shallow, Slow Slip Event in Eastern Taiwan

et al. 2019

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“…The clay gouges associated with the aseismic slip on this fault section (Figure c) are rich in weak minerals, such as saponite and other smectites (Kaduri et al, ). These low friction minerals have been observed as well along the creeping segments of the San Andreas Fault in California, and the Long Valley Fault in Taiwan (Moore & Rymer, ; Thomas et al, ). Along the Izmit creeping section, similar detailed analysis of rocks compositions in the fault zone remain to be done.…”

Section: Discussionmentioning

confidence: 91%

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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“…Fault zones that show the opposite behaviour, in which M ps /M cs is 80 per cent, are consistently located near parts of the fault surface that have interseismic creep rates similar to the far-field loading rate (e.g. the Parkfield section of the San Andreas Fault ) and the Longitudinal Valley Fault in Taiwan (Thomas et al 2014)). For the high M ps /M cs events there is limited locking around the co-seismic rupture, therefore post-seismic creep is not limited by the elastic resistance caused by adjacent locked zones.…”

Section: E E P P O S T -S E I S M I C D E F O R M Atmentioning

confidence: 99%

“…Recent studies suggest faults that creep extensively during the interseismic period also experience large amounts of post-seismic afterslip relative to co-seismic slip (Heki et al 1997;Furuya & Satyabala 2008;Barbot et al 2009; Thomas et al 2014). This observation implies that the amount of afterslip is related to the degree of locking of the fault zone around the co-seismic slip patch, and the magnitude of the co-seismic stress changes.…”

Section: Introductionmentioning

confidence: 99%

Fault mechanics and post-seismic deformation at Bam, SE Iran

Wimpenny¹,

Copley²,

Ingleby

2017

Geophysical Journal International

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S U M M A R YThe extent to which aseismic deformation relaxes co-seismic stress changes on a fault zone is fundamental to assessing the future seismic hazard following any earthquake, and in understanding the mechanical behaviour of faults. Here we use models of stress-driven afterslip and viscoelastic relaxation, in conjunction with post-seismic InSAR measurements, to show that there has been minimal release of co-seismic stress changes through post-seismic deformation following the 2003 M w 6.6 Bam earthquake. Our analysis indicates the faults at Bam remain predominantly locked, suggesting that the co-plus interseismically accumulated elastic strain stored downdip of the 2003 rupture patch may be released in a future M w 6 earthquake. Our observations and models also provide an opportunity to probe the growth of topography at Bam. We find that, for our modelled afterslip distribution to be consistent with forming the sharp step in the local topography over repeated earthquake cycles, and also to be consistent with the geodetic observations, requires either (1) far-field tectonic loading equivalent to a 2-10 MPa deviatoric stress acting across the fault system, which suggests it supports stresses 60-100 times less than classical views of static fault strength, or (2) that the fault surface has some form of mechanical anisotropy, potentially related to corrugations on the fault plane, that controls the sense of slip.

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Spatiotemporal evolution of seismic and aseismic slip on the Longitudinal Valley Fault, Taiwan

Cited by 90 publications

References 91 publications

Testing the Influence of Static and Dynamic Stress Perturbations On the Occurrence of a Shallow, Slow Slip Event in Eastern Taiwan

Testing the Influence of Static and Dynamic Stress Perturbations On the Occurrence of a Shallow, Slow Slip Event in Eastern Taiwan

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

Fault mechanics and post-seismic deformation at Bam, SE Iran

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