Crustal deformation in northwestern Arabia from GPS measurements in Syria: Slow slip rate along the northern Dead Sea Fault

Summary A variety of slow slip events at subduction zones have been observed. They can be stress meters for monitoring the stress state of megathrust faults during their earthquake cycles. In this study, we focus on long-term slow slip events (LSSEs) recurring at downdip portions of megathrust faults among such slow earthquakes. Data analyses and simulation studies of LSSEs have so far been executed independently. In atmosphere and ocean sciences, data assimilations that optimally combine data analyses and simulation studies have been developed. We develop a method for estimating frictional properties and monitoring slip evolution on an LSSE fault, with a sequential data assimilation method, the ensemble Kalman filter (EnKF). We executed numerical twin experiments for the Bungo Channel LSSE fault in southwest Japan to validate the method. First, based on a rate- and state-dependent friction law, we set a rate-weakening circular LSSE patch on the rate-strengthening flat plate interface, whose critical nucleation size is larger than that of the patch, and reproduced the observed Bungo Channel LSSEs with recurrence times of approximately 7 yr and slip durations of 1 yr. Then, we synthesized the observed data of surface displacement rates at uniformly distributed stations with noises from the simulated slip model. Using our EnKF method, we successfully estimated the frictional parameters and the slip rate evolution after a few cycles. Secondly, we considered the effect of the megathrust fault existing in the updip portion of the LSSE fault, as revealed by kinematic inversion studies of Global Navigation Satellite System (GNSS) data and added this locked region with a slip deficit rate in the model. We estimated the slip rate on the locked region only kinematically, but the quasi-dynamic equation of motion in each LSSE fault cell includes the stress term arising from the locked region. Based on this model, we synthesized the observed surface displacement rate data for the actual distribution of GNSS stations and executed EnKF estimations including the slip rate on the locked region. The slip rate on the locked region could be quickly retrieved. Even for the actual distribution of GNSS stations, we could successfully estimate frictional parameters and slip evolution on the LSSE fault. Thus, our twin numerical experiments showed the validity of our EnKF method, although we need further studies for actual GNSS data analyses.

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Slow slip rate and excitation efficiency of deep low-frequency tremors beneath southwest Japan

Tectonophysics ◽

10.1016/j.tecto.2017.11.016 ◽

2018 ◽

Vol 722 ◽

pp. 314-323 ◽

Cited By ~ 2

Author(s):

Kumiko Daiku ◽

Yoshihiro Hiramatsu ◽

Takanori Matsuzawa ◽

Tomoyuki Mizukami

Keyword(s):

Low Frequency ◽

Slip Rate ◽

Slow Slip ◽

Southwest Japan ◽

Excitation Efficiency

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Late Pleistocene extension and strike-slip in the Dead Sea Basin

Geological Magazine ◽

10.1017/s001675680400963x ◽

2004 ◽

Vol 141 (5) ◽

pp. 565-572 ◽

Cited By ~ 25

Author(s):

YUVAL BARTOV ◽

AMIR SAGY

Keyword(s):

Internal Structure ◽

Slip Rate ◽

Dead Sea ◽

Strike Slip ◽

Normal Faults ◽

Small Scale ◽

Dead Sea Basin ◽

Pull Apart Basin ◽

Western Border ◽

The Dead

A newly discovered active small-scale pull-apart (Mor structure), located in the western part of the Dead Sea Basin, shows recent basin-parallel extension and strike-slip faulting, and offers a rare view of pull-apart internal structure. The Mor structure is bounded by N–S-trending strike-slip faults, and cross-cut by low-angle, E–W-trending normal faults. The geometry of this pull-apart suggests that displacement between the two stepped N–S strike-slip faults of the Mor structure is transferred by the extension associated with the normal faults. The continuing deformation in this structure is evident by the observation of at least three deformation episodes between 50 ka and present. The calculated sinistral slip-rate is 3.5 mm/yr over the last 30 000 years. This slip rate indicates that the Mor structure overlies the currently most active strike-slip fault within the western border of the Dead Sea pull-apart. The Mor structure is an example of a small pull-apart basin developed within a larger pull-apart. This type of hierarchy in pull-apart structures is an indication for their ongoing evolution.

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Slip-rate-dependent friction as a universal mechanism for slow slip events

Nature Geoscience ◽

10.1038/s41561-020-0627-9 ◽

2020 ◽

Vol 13 (10) ◽

pp. 705-710

Author(s):

Kyungjae Im ◽

Demian Saffer ◽

Chris Marone ◽

Jean-Philippe Avouac

Keyword(s):

Slip Rate ◽

Slow Slip ◽

Slow Slip Events ◽

Rate Dependent ◽

Universal Mechanism

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Slow slip predictions based on granite and gabbro friction data compared to GPS measurements in northern Cascadia

Journal of Geophysical Research Atmospheres ◽

10.1029/2008jb006142 ◽

2009 ◽

Vol 114 (B9) ◽

Cited By ~ 49

Author(s):

Yajing Liu ◽

James R. Rice

Keyword(s):

Slow Slip ◽

Gps Measurements

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Active tectonics of the Eastern Mediterranean region: deduced from GPS, neotectonic and seismicity data

Annals of Geophysics ◽

10.4401/ag-3892 ◽

1997 ◽

Vol 40 (3) ◽

Author(s):

A. Barka ◽

R. Reilinger

Keyword(s):

Mediterranean Region ◽

Eastern Mediterranean ◽

Eastern Mediterranean Region ◽

Slip Rate ◽

Strike Slip ◽

Central Anatolia ◽

Western Anatolia ◽

Eastern Anatolia ◽

Gps Measurements ◽

Isparta Angle

This paper reviews the main tectonic features of the Eastern Mediterranean region combining the recent information obtained from GPS measurements, seismicity and neotectonic studies. GPS measurements reveal that the Arabian plate moves northward with respect to Eurasia at a rate of 23 ± 1 mm/yr, 10 mm/yr of this rate is taken up by shortening in the Caucasus. The internal deformation in Eastern Anatolia by conjugate strike-slip faulting and E-W trending thrusts, including the Bitlis frontal thrust, accommodates approximately a 15 mm/yr slip rate. The Northeast Anatolian fault, which extends from the Erzincan basin to Caucasus accommodates about 8 ± 5 mm/yr of left-lateral motion. The neotectonic fault pattern in Eastern Anatolia suggests that the NE Anatolian block moves in an E-ENE direction towards the South Caspian Sea. According to the same data, the Anatolian-Aegean block is undergoing a counter-clockwise rotation. However, from the residuals it appears that this solution can only be taken as a preliminary approximation. The Eulerian rotation pole indicates that slip rate along the North Anatolian fault is about 26 ± 3 mm/yr. This value is 10 mm/yr higher than slip rates obtained from geological data and historical earthquake records and it includes westward drift of the Pontides of a few millimetres/year or more. GPS measurements reveal that the East Anatolian fault accommodates an 11 ± 1 mm/yr relative motion. GPS data suggest that Central Anatolia behaves as a rigid block, but from neotectonic studies, it clearly appears that it is sliced by a number of conjugate strike-slip faults. The Isparta Angle area might be considered a major obstacle for the westward motion of the Anatolian block (Central and Eastern Anatolia). The western flank of this geological structure, the Fethiye-Burdur fault zone appears to be a major boundary with a slip rate of 15-20 mm/yr. The Western Anatolian grabens take up a total of 15 mm/yr NE-SW extension. The fact that motions in Central Anatolia relative to Eurasia, are 15-20 mm/yr while in Western Anatolia and Aegean Sea they are 30-40 mm/yr could suggest that Western Anatolia decouples from Central Anatolia and the Isparta Angle by the Fethiye-Burdur fault zone and Eski?ehir fault. It is also hypothesized that the differentiation of tectonic styles and velocities in the Anatolian-Aegean block are related to differences between the slabs lying under the Cyprus and Hellenic arcs.

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Slow slip events are regular earthquakes

10.21203/rs.3.rs-448196/v1 ◽

2021 ◽

Author(s):

Huihui Weng

Keyword(s):

Wave Speed ◽

Physical Mechanism ◽

Three Dimensional ◽

Slip Rate ◽

Slow Slip ◽

S Wave ◽

Slow Slip Events ◽

Fundamental Model ◽

Wave Effects ◽

Dynamic Wave

Abstract Slow slip events usually occur downdip of seismogenic zones in subduction megathrusts and crustal faults, with rupture speeds much slower than earthquakes. The empirical moment-duration scaling relation can help constrain the physical mechanism of slow slip events, yet it is still debated whether this scaling is linear or cubic and a fundamental model unifying slow slip events and earthquakes is still lacking. Here I present numerical simulations that show that slow slip events are regular earthquakes with negligible dynamic-wave effects. A continuum of rupture speeds, from arbitrarily-slow speeds up to the S-wave speed, is primarily controlled by the stress drop and a transition slip rate above which the fault friction transitions from rate-weakening behaviour to rate-strengthening behaviour. This continuum includes tsunami earthquakes, whose rupture speeds are about one-third of the S-wave speed. These numerical simulation results are predicted by the three-dimensional theory of dynamic fracture mechanics of elongated ruptures. This fundamental model unifies slow slip events and earthquakes, reconciles the observed moment-duration scaling relations, and opens new avenues for understanding earthquakes through investigations of the kinematics and dynamics of frequently occurring slow slip events.

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