Your search keyword '"Yi-Ying Wen"' showing total 8 results

1. The kinematic source analysis for 2018 Mw 6.4 Hualien, Taiwan earthquake

Author

Yuan-Hsi Lee, Strong Wen, Yi Ying Wen, and Kuo En Ching

Subjects

lcsh:Geology, Atmospheric Science, lcsh:QE1-996.5, Earth and Planetary Sciences (miscellaneous), lcsh:G1-922, Kinematics, Oceanography, lcsh:Geography (General), Seismology, Geology

Abstract

The 2018 Mw 6.4 Hualien earthquake struck the eastern Taiwan and caused serious damage. We investigate the rupture properties of the 2018 Hualien earthquake by inverting teleseismic body wave and forward modeling GPS coseismic deformation. The rupture process and slip pattern of preferred model explain both the far-field (teleseismic data) and near-field (GPS) observations. The results show that the 2018 Hualien mainshock ruptured southward on two fault segments, with a weak but fast initiation (3.0 km s-1) in the main west-dipping segment F1 and slow (2.0 km s-1) yet significant slip on shallow east-dipping segment F2. In the past few years, several moderate-sized events, which struck eastern Taiwan and caused strong ground shaking and some seismic damage, are considered occurring on the west-dipping fault. Additional investigations are required to building up the knowledge of this not wellknown region.

Published

2019

2. Source and strong-motion characteristics of two M > 6 buried earthquakes in southwest Taiwan

Author

Yi Ying Wen, Chun Hsiang Kuo, Yin Tung Yen, and Kuo En Ching

Subjects

High peak, lcsh:QB275-343, Strong motion generation area, Southern taiwan, lcsh:Geodesy, lcsh:QE1-996.5, lcsh:Geography. Anthropology. Recreation, Geology, Pore fluid pressure, Rupture directivity, Slip (materials science), Directivity, lcsh:Geology, Seismic hazard, lcsh:G, Space and Planetary Science, Seismic moment, Nonlinear site response, Ground shaking, Seismology

Abstract

We used near-field strong-motion data to investigate the complex combination of source effect and site response for two recent disastrous earthquakes in southwest Taiwan. We estimated strong-motion generation areas (SMGAs) of 2.8 km × 2.8 km and 6.0 km × 4.2 km in a frequency band of 0.4–10 Hz for the 2010 Jiashian and 2016 Meinong earthquakes, respectively. The high-stress drops of 26.2 and 17.0 MPa for these two buried events were potentially related to the small dimension and deep rupture. Our results revealed that both earthquakes exhibited westward rupture directivity, whereas the 2016 Meinong event exhibited a stronger directivity effect because of the consistency between the propagation and slip directions. The localized high peak ground velocity (PGV) patch and the nonlinear site response could be attributed to the soft sediment with high pore fluid pressure and low-velocity structure beneath this region. However, the greater seismic moment and closer faulting location to the thick-mudstone-layer region for the 2016 Meinong event reinforced the strong ground shaking and serious damage over the broad area. This implies that this thick-mudstone-layer region in southern Taiwan plays a crucial role in earthquake response, and an investigation of characteristic site effects should be conducted for seismic hazard mitigation.Graphic abstract

Published

2020

3. Source Characteristics of the Northern Longitudinal Valley, Taiwan Derived from Broadband Strong-Motion Simulation

Author

Yi Ying Wen

Subjects

010504 meteorology & atmospheric sciences, Motion simulation, Event (relativity), 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Seismic hazard, Geochemistry and Petrology, Broadband, Range (statistics), Motion generation, Ground shaking, Seismology, Geology, Aftershock, 0105 earth and related environmental sciences

Abstract

The 2014 M L 5.9 Fanglin earthquake occurred at the northern end of the aftershock distribution of the 2013 M L 6.4 Ruisui event and caused strong ground shaking and some damage in the northern part of the Longitudinal Valley. We carried out the strong-motion simulation of the 2014 Fanglin event in the broadband frequency range (0.4–10 Hz) using the empirical Green’s function method and then integrated the source models to investigate the source characteristics of the 2013 Ruisui and 2014 Fanglin events. The results show that the dimension of strong motion generation area of the 2013 Ruisui event is smaller, whereas that of the 2014 Fanglin event is comparable with the empirical estimation of inland crustal earthquakes, which indicates the different faulting behaviors. Furthermore, the localized high PGV patch might be caused by the radiation energy amplified by the local low-velocity structure in the northern Longitudinal Valley. Additional study issues are required for building up the knowledge of the potential seismic hazard related to moderate-large events for various seismogenic areas in Taiwan.

Published

2017

4. Seismicity variations prior to the 2016 ML 6.6 Meinong, Taiwan earthquake

Author

Yi Ying Wen and Chien Chih Chen

Subjects

021110 strategic, defence & security studies, Atmospheric Science, lcsh:QE1-996.5, 0211 other engineering and technologies, lcsh:G1-922, 02 engineering and technology, Induced seismicity, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, lcsh:Geology, Earth and Planetary Sciences (miscellaneous), lcsh:Geography (General), Geology, Seismology, 0105 earth and related environmental sciences

Abstract

The 2016 ML 6.6 Meinong earthquake struck southern Taiwan and caused serious damage due to the strong ground shaking. Anomalous seismicity spatiotemporal signature changes were identified prior to the 2016 Meinong event. We investigate the seismicity rate changes associated with the 2016 Meinong mainshock by applying the region-time-length (RTL) algorithm. The temporal result reveals a long obvious seismic quiescence stage soon after the 2012 Wutai event lasting until the 2016 Meinong mainshock. The spatial pattern of different background period lengths all exhibit that the 2016 Meinong event occurred near the abnormal seismic quiescence patch. Our study shows that the spatiotemporal information of the seismicity change could be a useful indication for potential seismic-hazard assessment.

Published

2017

5. Source characteristics of moderate-to-strong earthquakes in the Nantou area, Taiwan: insight from strong ground motion simulations

Author

Yi Ying Wen, Strong Wen, Yin Tung Yen, and Shen-Yu Chao

Subjects

Buried fault, 010504 meteorology & atmospheric sciences, Strong motion generation area, lcsh:Geodesy, Fault (geology), 010502 geochemistry & geophysics, 01 natural sciences, Stress drop, 0105 earth and related environmental sciences, lcsh:QB275-343, geography, geography.geographical_feature_category, lcsh:QE1-996.5, lcsh:Geography. Anthropology. Recreation, Geology, High stress, lcsh:Geology, Strong ground motion, Seismic hazard, lcsh:G, Space and Planetary Science, Function method, human activities, Seismology

Abstract

In Taiwan, the Nantou area is a seismically active region where several moderate events have occurred, causing some disasters during the past century. Here, we applied the strong ground motion simulation with the empirical Green’s function method to investigate the source characteristics for the eight moderate blind-fault events that struck the Nantou area in 1999 and 2013. The results show that for these Nantou events, a high stress drop and focal depth dependence were noted, which might be related to the immature buried fault in this area. From the viewpoint of seismic hazard prevention and preparation, future earthquake scenarios that include high stress drop should be applied to more analyses, especially the moderate-to-large events originating from the immature blind faulting. Graphical abstract .

Published

2017

6. Crustal thickening and extension induced by the Great Sumatra–Andaman earthquake of 26 December 2004: revealed by the seismic moment tensor element Mrr

Author

Shu Kun Hsu, Yi Ying Wen, Jing Yi Lin, Jean Claude Sibuet, Wen Nan Wu, and C.-L. Lo

Subjects

Focal mechanism, Geophysics, Subduction, Geochemistry and Petrology, Slab pull, Epicenter, Slab, Intraplate earthquake, Seismic moment, Slip (materials science), Oceanography, Seismology, Geology

Abstract

In a complex geological environment, it is generally difficult to assimilate a complete understanding of the main stress regime without being distracted by various fault configurations. In this study, we examine the changes in radial seismic moment (Mrr) of earthquakes that occurred in the Sumatra area. This approach allows for simplification of the various focal mechanism solutions by compressive and extensional slip vectors. The results show that the epicenter of the 2004 mainshock is located near the area where the accumulated Mrr was highest during the inter-seismic period. Simultaneously, a pattern of negative accumulated Mrr observed at depths between 40 and 100 km suggests a down-dip extension mechanism caused by the slab pull effect, which could be strengthened by the locking procedure in shallow portions of the slab. Moreover, the right-lateral strike-slip Sumatra Fault and the left-lateral oceanic fracture zones exhibited positive and negative accumulated Mrr prior to and immediately after the 2004 mainshock. This transform of Mrr indicates stress release associated with the unlocking of the asperities during the earthquake. Therefore, the distinctly different Mrr patterns for the inter- and post-seismic period suggest that the occurrence of a substantial earthquake could change the intraplate stress state.

Published

2014

7. Hybrid Ground Motion Simulation for the 2013 ML 6.4 Ruisui, Taiwan Earthquake

Author

Chun Hsiang Kuo, Strong Wen, Shiann-Jong Lee, Yin Tung Yen, Yen Yu Lin, and Yi Ying Wen

Subjects

Atmospheric Science, Peak ground acceleration, Seismic microzonation, 010504 meteorology & atmospheric sciences, lcsh:QE1-996.5, lcsh:G1-922, Environmental Seismic Intensity scale, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Incremental Dynamic Analysis, 2013 Ruisui earthquake, Physics::Geophysics, lcsh:Geology, Strong ground motion, Hybrid ground motion simulation, Seismic hazard, Earthquake simulation, Earth and Planetary Sciences (miscellaneous), Earthquake shaking table, lcsh:Geography (General), Geology, Seismology, 0105 earth and related environmental sciences

Abstract

The 2013 M_L 6.4 Ruisui earthquake struck a seismic gap around the northern part of the Longitudinal Valley where rare earthquakes have occurred for at least two decades. Seismic data with different frequency bands connote a diverse scale of source characteristics. The slip model derived by a previous study using long-period seismic data provided us with the preliminary earthquake source properties in low-frequency energy radiation. However, the high-frequency part of the seismic energy needs to be considered for the strong motions in the comprehensive frequency band. As a case study, we carried out broadband strong motion simulations through the hybrid scheme, which simulated waveforms combining the low-frequency motions (frequency-wavenumber integration method) and high-frequency motions (empirical Green's function method) to reveal the strong ground motion and source characteristics of the 2013 Ruisui earthquake. The results show that even though the local structure is complicated this hybrid simulation can effectively rebuild the overall broadband strong ground motion characteristics for the 2013 Ruisui earthquake. Additional study issues are required to better understand the nature of localized high peak ground acceleration and the related seismic hazards for future earthquakes.

Published

2016

8. Slip Partition of the 26 December 2006 Pingtung, Taiwan (M 6.9, M 6.8) Earthquake Doublet Determined from TeleseismicWaveforms

Author

Kuo Fong Ma, Yi Ying Wen, and Yin Tung Yen

Subjects

Seismic gap, Atmospheric Science, Tectonics, Subduction, Hypocenter, Interplate earthquake, Earth and Planetary Sciences (miscellaneous), Waveform, Bathymetry, Slip (materials science), Oceanography, Geology, Seismology

Abstract

Teleseicmic vertical P waves of an earthquake doublet occurring on 26 December 2006 offshore southwestern Taiwan are analyzed to recover spatial slip distribution. Ground-displacement records for period 0.01-0.5 Hz are inverted using linear inversion for finite fault analysis. Waveform inversion results show that a dual segment fault of different strike is necessary for the first event to explain teleseismic waveforms. The trend in fault geometry, thus, inferred was coincidentally consistent with the bathymetry in the fault rupture area, suggesting the possible tectonic structure controlling fault propagation. Both earthquakes show larger slip in the asperities near the hypocenter and there are two main asperities of similar moments. The first event ruptured along a high angle eastern dipping plane while the second event ruptured along a low-angle western dipping fault plane. The spatial distribution of the Pingtung earthquake doublet shows a compensative and conjugate relationship, and the seismic moments of the earthquake doublet were 2.7×10^26 and 1.8×10^26 dyne-cm, respectively. The stress drops corresponding to the asperities of the two earthquakes have values of 3 to 4 bars, individually, similar to the values observed in other subduction zones.

Published

2008