An ancient shallow slip event on the Mentawai segment of the Sunda megathrust, Sumatra

Philibosian, B.; Sieh, Kerry; Natawidjaja, D. H.; Chiang, H.; Shen, Chuan‐Chou; Suwargadi, B. W.; Hill, Emma M.; Edwards, R. Lawrence

doi:10.1029/2011jb009075

Cited by 20 publications

(26 citation statements)

References 42 publications

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“…Therefore, while our model constrains slip on the main seismogenic portion of the megathrust based on previous rupture cycles, weak constraints trenchwards of the islands allow for more complex patterns of interseismic and coseismic slip near the trench (e.g. as suggested for Tohoku, Japan by Perfettini & Avouac 2014) that are not yet well resolved by the palaeogeodetic record (Philibosian et al 2012).…”

Section: Discussionmentioning

confidence: 86%

“…8b): variance also increases further away from the islands towards the most downdip portion of the fault. Constraining slip near the trench is further complicated as near-trench slip will generate subsidence at most locations on the Mentawai Islands (Hill et al 2012;Philibosian et al 2012): yet, all the coral data points record coseismic uplift. Therefore, while our model constrains slip on the main seismogenic portion of the megathrust based on previous rupture cycles, weak constraints trenchwards of the islands allow for more complex patterns of interseismic and coseismic slip near the trench (e.g.…”

Section: Discussionmentioning

confidence: 99%

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Assessing tsunami hazard using heterogeneous slip models in the Mentawai Islands, Indonesia

Griffin

Pranantyo

Kongko³

et al. 2016

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Tsunami hazard maps are generated for the coastline of the Mentawai Islands, West Sumatra, Indonesia, to support evacuation and disaster response planning. A random heterogeneous slip generator is used to forward model a suite of earthquake rupture scenarios on the Mentawai Segment of the Sunda Subduction Zone. Up to 1000 rupture models that fit constraints provided by coral and geodetic records of coseismic vertical deformation from major earthquakes in 1797, 1833 and 2007 are used to model inundation and to define a maximum inundation zone that envelopes all of these scenarios. Comparison with single-scenario hazard assessments developed by experts and agreed through scientific consensus shows that there is value in modelling a suite of scenarios in order to obtain a more robust and conservative estimate of potential inundated areas. Although both the model presented here and the single-scenario models are based on assumptions about the characteristics of future events using knowledge of past events, by sampling a range of plausible outcomes we gain a more robust estimate of which areas may be inundated during a tsunami within the bounds of the assumptions applied. Purpose of the hazard assessmentTo plan for tsunami evacuation at the community level, information is needed about which areas of the coast may be inundated during a tsunami event. Based on this information, communities can identify safe evacuation areas outside the inundation zone and the most efficient routes to reach these safe areas. For a government considering life safety as the first priority in managing a disaster, it is reasonable to plan evacuation areas based on a deterministic assessment of 'maximum credible' or 'worst-case' scenarios, to the extent that scientific knowledge, conservatism and the assumptions that we make can define these scenarios. In contrast, disaster management strategies targeting other losses (e.g. economic losses) accept a different level of risk and are designed for a certain level of risk tolerance based on probabilistic hazard assessments.

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Section: Discussionmentioning

confidence: 86%

Section: Discussionmentioning

confidence: 99%

Assessing tsunami hazard using heterogeneous slip models in the Mentawai Islands, Indonesia

Griffin

Pranantyo

Kongko³

et al. 2016

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“…[], vertical deformation measurements on the Mentawai Islands are largely insensitive to the behavior of the shallow megathrust (see coseismic model resolution maps in Figures S19 and S21). The shallow portion of the Mentawai segment is known to rupture seismically, individually during the 2010 tsunami earthquake [e.g., Hill et al ., ] and an ancient shallow event [ Philibosian et al ., ], and likely in conjunction with the intermediate‐depth seismogenic zone in 1797 and 1833, based on historical tsunami reports summarized by Natawidjaja et al . [].…”

Section: Discussion and Modeling Of Coseismic And Interseismic Behavimentioning

confidence: 95%

Earthquake supercycles on the Mentawai segment of the Sunda megathrust in the seventeenth century and earlier

et al. 2017

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Over at least the past millennium, the Mentawai segment of the Sunda megathrust has failed in sequences of closely timed events rather than in single end‐to‐end ruptures—each the culmination of an earthquake “supercycle.” Here we synthesize the sixteenth‐ and seventeenth‐century coral microatoll records into a chronology of interseismic and coseismic vertical deformation. We identify at least five discrete uplift events in about 1597, 1613, 1631, 1658, and 1703 that likely correspond to large megathrust ruptures. This sequence contrasts with the following supercycle culmination, which involved only two large ruptures in 1797 and 1833. Fault slip modeling suggests that together the five cascading ruptures involved failure of the entire Mentawai segment. Interseismic deformation rates also changed after the onset of the rupture sequence, as they did after the 1797 earthquake. We model this change as an altered distribution of fault coupling, presumably triggered by the ~1597 rupture. We also analyze the far less continuous microatoll record between A.D. 1 and 1500. While we cannot confidently delineate the extent of any megathrust rupture during that period, all evidence suggests that individual major ruptures involve only part of the Mentawai segment, often overlap below the central Mentawai Islands, often trigger coupling changes, and occur in clusters that cumulatively cover the entire Mentawai segment at the culmination of each supercycle. It is clear that each Mentawai rupture sequence evolves uniquely in terms of the order and grouping of asperities that rupture, suggesting heterogeneities in fault frictional properties at the ~100 km scale.

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“…However, it is clear that the seismic behavior of the shallow portion of the megathrust appears to be more complex than previously thought. Specifically, the shallow region of megathrusts can both participate in large earthquakes, as exemplified by the 2011 M w 9.0 Tohoku‐oki earthquake, as well as host tsunami earthquakes, as exemplified by the 1314 and 2010 M w 7.8 Mentawai, 1992 M w 7.6 Nicaragua, 1994 M w 7.8 Java, and 1996 M w 7.5 Peru earthquakes [ Hill et al , ; Philibosian et al , ; Polet and Kanamori , ]. The question that needs to be addressed is, therefore, what physical conditions and properties control the spatial and temporal pattern of shallow seismic ruptures?…”

Section: Discussionmentioning

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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An ancient shallow slip event on the Mentawai segment of the Sunda megathrust, Sumatra

Cited by 20 publications

References 42 publications

Assessing tsunami hazard using heterogeneous slip models in the Mentawai Islands, Indonesia

Assessing tsunami hazard using heterogeneous slip models in the Mentawai Islands, Indonesia

Earthquake supercycles on the Mentawai segment of the Sunda megathrust in the seventeenth century and earlier

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

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An ancient shallow slip event on the Mentawai segment of the Sunda megathrust, Sumatra

Cited by 20 publications

References 42 publications

Assessing tsunami hazard using heterogeneous slip models in the Mentawai Islands, Indonesia

Assessing tsunami hazard using heterogeneous slip models in the Mentawai Islands, Indonesia

Earthquake supercycles on the Mentawai segment of the Sunda megathrust in the seventeenth century and earlier

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

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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