1909 Taipei Earthquake Ground Motion Simulation

Liao, Yicheng; Yen, Yin-Tung; Lee, Shiann‐Jong; Fong, Kuo

doi:10.3319/tao.2016.03.02.01(tem)

Cited by 3 publications

(2 citation statements)

References 13 publications

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“…Deterministic ground-motion prediction, prediction using earthquake scenario simulations, is attracting much research interest. To reliably simulate these scenarios requires comprehensive knowledge of fault models, especially knowledge of the geometry and slip heterogeneity of finite faults (Liao et al 2016;Wen et al 2016). …”

Section: Introductionmentioning

confidence: 99%

Synthetic Ground-Motion Simulation Using a Spatial Stochastic Model with Slip Self-Similarity: Toward Near-Source Ground-Motion Validation

Lee

Fong²,

Hsieh³

et al. 2016

Terr. Atmos. Ocean. Sci.

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Near-fault ground motion is a key to understanding the seismic hazard along a fault and is challenged by the ground motion prediction equation approach. This paper presents a developed stochastic-slip-scaling source model, a spatial stochastic model with slipped area scaling toward the ground motion simulation. We considered the near-fault ground motion of the 1999 Chi-Chi earthquake in Taiwan, the most massive near-fault disastrous earthquake, proposed by Ma et al. (2001) as a reference for validation. Three scenario source models including the developed stochastic-slip-scaling source model, meanslip model and characteristic-asperity model were used for the near-fault ground motion examination. We simulated synthetic ground motion through 3D waveforms and validated these simulations using observed data and the ground-motion prediction equation (GMPE) for Taiwan earthquakes. The mean slip and characteristic asperity scenario source models over-predicted the near-fault ground motion. The stochastic-slip-scaling model proposed in this paper is more accurately approximated to the near-fault motion compared with the GMPE and observations. This is the first study to incorporate slipped-area scaling in a stochastic slip model. The proposed model can generate scenario earthquakes for predicting ground motion.

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Section: Introductionmentioning

confidence: 99%

Synthetic Ground-Motion Simulation Using a Spatial Stochastic Model with Slip Self-Similarity: Toward Near-Source Ground-Motion Validation

Lee

Fong²,

Hsieh³

et al. 2016

Terr. Atmos. Ocean. Sci.

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“…They demonstrated that, despite the complex structure in eastern Taiwan, their hybrid approach successfully replicated the overall characteristics of broadband ground motion for the 2013 Ruisui earthquake. Liao et al (2016) performed a hybrid method comprising both the spectral-element and the empirical Green's function methods to simulate the ground motion of the 1909 Taipei earthquake. Their study indicated that the moment magnitude of the 1909 Taipei earthquake was either 7.3 with a stress drop of 30 bars, or between 6.8 and 7.3, but with a higher stress drop of > 100 bars.…”

mentioning

confidence: 99%

Preface to the Special Issue on “Taiwan Earthquake Model: Seismic Hazard Assessment and Earthquake Scenario”

Rau¹,

Fong²

2016

Terr. Atmos. Ocean. Sci.

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An Investigation of the Reliability of the Taiwan Earthquake Model PSHA2015

Wang

Lee

Chan

et al. 2016

Seismological Research Letters

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The Taiwan Earthquake Model (TEM) has had a new probabilistic seismic-hazard analysis (PSHA) model for determining the probability of exceedance (PoE) of the ground motion over a specified period in Taiwan. We conducted several tests to investigate the adequacy of the seismic source parameters adopted by the TEM in 2015 (TEM PSHA2015). The observed maximal peak ground accelerations (PGAs) of the M L > 4:0 mainshocks from 1993 to 2015 were used to test the predicted PGA from areal and subduction zone sources based on a timeindependent Poisson distribution. This comparison excluded the observations from the 1999 Chi-Chi earthquake, because this was the only earthquake associated with the identified active fault in the testing period. We used tornado diagrams to analyze the sensitivities of these source parameters to the ground-motion values of the PSHA. This study showed that the predicted PGA for a 63% PoE in the 23-year period corresponded to observations, confirming the applicability of the parameters to areal and subduction zone sources. We adopted disaggregation analysis to determine the contribution of each seismic source to the hazard for six metropolitan cities in Taiwan. Sensitivity tests on the seismogenic structure parameters indicated that slip rate and maximum magnitude are the dominant factors in the TEM PSHA2015. For densely populated faults in southwestern Taiwan, the assessed hazard level is more sensitive to the maximum magnitude of earthquakes than it is to the slip rate of active faults, creating concern for the possibility of larger earthquakes due to multiple-segment ruptures in this area, which has not yet been considered in the TEM PSHA2015. The source category disaggregation also suggested a seismic hazard over long periods in northern Taiwan due to subduction zone sources.

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1909 Taipei Earthquake Ground Motion Simulation

Cited by 3 publications

References 13 publications

Synthetic Ground-Motion Simulation Using a Spatial Stochastic Model with Slip Self-Similarity: Toward Near-Source Ground-Motion Validation

Synthetic Ground-Motion Simulation Using a Spatial Stochastic Model with Slip Self-Similarity: Toward Near-Source Ground-Motion Validation

Preface to the Special Issue on “Taiwan Earthquake Model: Seismic Hazard Assessment and Earthquake Scenario”

An Investigation of the Reliability of the Taiwan Earthquake Model PSHA2015

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