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

Meade, Brendan J.; Klinger, Yann; Hetland, E. A.

doi:10.1785/0120130006

Cited by 74 publications

(91 citation statements)

References 102 publications

(109 reference statements)

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“…Previous researchers investigating postseismic deformation following the Sumatran earthquakes estimated mantle viscosities in this region between 10 17 to 10 19 Pa s [ Lubis et al , ; Panet et al , ; Pollitz and Banerjee , ]. The value of the mantle viscosity can depend on the time window of geodetic observations examined; examining geodetic observations late in the interseismic period of the earthquake cycle can yield mantle viscosities on average 1 order of magnitude higher than geodetic observations early in the interseismic period of the earthquake cycle [ Meade et al , ]. In addition, some studies of early stage postseismic deformation assume predominantly viscoelastic deformation and do not account for afterslip, employing instead transient rheologies to explain different time‐dependent decay patterns of geodetic time series [e.g., Panet et al , ].…”

Section: Inversion Methodsmentioning

confidence: 99%

Afterslip following the 2007 M_w 8.4 Bengkulu earthquake in Sumatra loaded the 2010 M_w 7.8 Mentawai tsunami earthquake rupture zone

et al. 2016

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The 12 September 2007 Mw 8.4 Bengkulu earthquake in Sumatra marked the first in a modern series of large earthquakes along the Mentawai section of the Sunda megathrust. Understanding the spatial distribution of coseismic slip and ensuing afterslip is important for assessing seismic hazard in neighboring unruptured regions of the megathrust. We reestimate the spatial distribution of coseismic slip during this earthquake with improved coseismic offsets from the Sumatran GPS Array (SuGAr) and estimate afterslip following this earthquake with SuGAr postseismic time series spanning ∼6.3 years after the earthquake. We invert for the spatiotemporal distribution of afterslip with the principal component analysis‐based inversion method (PCAIM), and we take into account viscoelastic deformation by incorporating into the inversion the estimation of strain within ductile deforming blocks located at asthenospheric depths. Our results suggest cumulative afterslip concentrated within, updip, and downdip of the 2007 coseismic rupture area and shallow afterslip that borders and overlaps the 2010 Mw 7.8 Mentawai earthquake rupture zone. The cumulative contribution of stress changes due to the coseismic event and the ensuing afterslip likely increased strain rates in the shallow portion of the megathrust adjacent to the Mentawai earthquake rupture area, potentially promoting its rupture in 2010.

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Section: Inversion Methodsmentioning

confidence: 99%

Afterslip following the 2007 M_w 8.4 Bengkulu earthquake in Sumatra loaded the 2010 M_w 7.8 Mentawai tsunami earthquake rupture zone

et al. 2016

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“…Viscous relaxation by power law flow was found to match the observed rapid decay of postseismic deformation observed following the 1992 Landers and 1999 Hector Mine earthquakes [ Freed and Bürgmann , ] and the 2002 Denali earthquake [ Freed et al ., ]. A linear biviscous Burgers body rheology, possibly representing transient creep following a stress step, has also been found to capture the rapidly decaying deformation following these and other strike‐slip earthquakes [e.g., Pollitz , , ; Hearn et al ., ] and has been used to model time‐dependent relaxation following recent subduction zone events [e.g., Pollitz et al ., ; Hoechner et al ., ; Hu and Wang , ; Meade et al ., ; Mikhailov et al ., ; Trubienko et al ., ; Broerse et al ., ; Wiseman et al ., ]. Freed et al .…”

Section: Model Setupmentioning

confidence: 99%

Stress‐driven relaxation of heterogeneous upper mantle and time‐dependent afterslip following the 2011 Tohoku earthquake

et al. 2016

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Understanding of postseismic deformation following great subduction zone earthquakes is complicated by the combined effects of viscoelastic relaxation of earthquake‐induced stresses in the upper mantle and time‐dependent afterslip on the megathrust. We integrate geodetic observations and constraints on afterslip from small repeating earthquakes on the megathrust to better distinguish contributions from these two postseismic processes. We have developed a three‐dimensional, spherical viscoelastic finite element model to study the postseismic deformation of the 2011 Mw9.0 Tohoku earthquake that has been recorded at unprecedented high resolution in space and time. We model stress‐driven afterslip in a 2 km thick weak shear zone away from historic rupture zones on the megathrust. We model both the viscoelastic relaxation of the upper mantle and shear zone deformation with a transient Burgers body rheology. The transient Kelvin viscosity is assumed to be one order of magnitude lower than that of the Maxwell viscosity. Viscoelastic relaxation of the mantle wedge alone causes postseismic uplift and seaward motion in the upper plate, opposite to the pattern from relaxation of just the oceanic upper mantle. Afterslip on the fault produces uplift updip of the afterslip zone and subsidence over its downdip edge and mostly seaward motion above the afterslip zone. The best fit Maxwell viscosity of the shear zone at depths ≤50 km is 1017 Pa s, constrained by afterslip estimates from repeating earthquakes. The optimal viscosities of the deep weak shear zone, continental mantle wedge, and oceanic upper mantle are determined to be 5 × 1017 Pa s, 3 × 1019 Pa s, and 5 × 1019 Pa s, respectively. The stress‐driven afterslip in the shear zone is up to ~3.5 m in the first 2 years after the earthquake, equivalent to an Mw8.4. Our model reproduces the first‐order pattern of the GPS observations both in horizontal and in vertical directions. Seafloor geodetic observations of subsidence and landward motions near the high‐slip zone of the earthquake provide evidence for a low‐viscosity asthenosphere below the oceanic lithosphere.

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“…Second, the slip rates of major faults derived from simple steady-state geodetic models have been shown to agree within error with those estimated from dating geological offsets100101. This suggests that strain rates are more or less steady for most of the earthquake cycle.…”

Section: Implications For Fault Mechanics and How Continents Deformmentioning

confidence: 67%

“…If all faults behave in a similar way, we can use observations from different faults, each at different points of the cycle, to infer the time-dependent behaviour of an individual fault. This approach has been used to establish a few key patterns of behaviour that any successful model must be able to reproduce11100. First, and with remarkably few exceptions, the deformation between earthquakes at major faults is focused around the fault (for example, Fig.…”

Section: Implications For Fault Mechanics and How Continents Deformmentioning

confidence: 99%

The role of space-based observation in understanding and responding to active tectonics and earthquakes

2016

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The quantity and quality of satellite-geodetic measurements of tectonic deformation have increased dramatically over the past two decades improving our ability to observe active tectonic processes. We now routinely respond to earthquakes using satellites, mapping surface ruptures and estimating the distribution of slip on faults at depth for most continental earthquakes. Studies directly link earthquakes to their causative faults allowing us to calculate how resulting changes in crustal stress can influence future seismic hazard. This revolution in space-based observation is driving advances in models that can explain the time-dependent surface deformation and the long-term evolution of fault zones and tectonic landscapes.

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

Cited by 74 publications

References 102 publications

Afterslip following the 2007 M_w 8.4 Bengkulu earthquake in Sumatra loaded the 2010 M_w 7.8 Mentawai tsunami earthquake rupture zone

Afterslip following the 2007 M_w 8.4 Bengkulu earthquake in Sumatra loaded the 2010 M_w 7.8 Mentawai tsunami earthquake rupture zone

Stress‐driven relaxation of heterogeneous upper mantle and time‐dependent afterslip following the 2011 Tohoku earthquake

The role of space-based observation in understanding and responding to active tectonics and earthquakes

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

Cited by 74 publications

References 102 publications

Afterslip following the 2007 Mw 8.4 Bengkulu earthquake in Sumatra loaded the 2010 Mw 7.8 Mentawai tsunami earthquake rupture zone

Afterslip following the 2007 Mw 8.4 Bengkulu earthquake in Sumatra loaded the 2010 Mw 7.8 Mentawai tsunami earthquake rupture zone

Stress‐driven relaxation of heterogeneous upper mantle and time‐dependent afterslip following the 2011 Tohoku earthquake

The role of space-based observation in understanding and responding to active tectonics and earthquakes

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Afterslip following the 2007 M_w 8.4 Bengkulu earthquake in Sumatra loaded the 2010 M_w 7.8 Mentawai tsunami earthquake rupture zone

Afterslip following the 2007 M_w 8.4 Bengkulu earthquake in Sumatra loaded the 2010 M_w 7.8 Mentawai tsunami earthquake rupture zone