Spatiotemporal evolution of seismic and aseismic slip on the Longitudinal Valley Fault, Taiwan

The Longitudinal Valley Fault (LVF) in eastern Taiwan is a high slip rate fault (about 5 cm/yr), which exhibits both seismic and aseismic slip. Deformation of anthropogenic features shows that aseismic creep accounts for a significant fraction of fault slip near the surface, whereas a fraction of th...

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Bibliographic Details
Published in:Journal of geophysical research. Solid earth 2014-06, Vol.119 (6), p.5114-5139
Main Authors: Thomas, Marion Y., Avouac, Jean-Philippe, Champenois, Johann, Lee, Jian-Cheng, Kuo, Long-Chen
Format: Article
Language:English
Subjects:
Accelerometers
Anthropogenic factors
Aseismic zones
Clay
creep
Creep (materials)
Deformation
Depth
Earth Sciences
Earthquakes
Evolution
Fault lines
Geological faults
Geophysics
Global positioning systems
GPS
Interferometric synthetic aperture radar
Interferometry
interseismic coupling
Inversions
Leveling
Methods
Plate tectonics
Positioning systems
Principal components analysis
Radar
Resolution
Rupture
Rupturing
SAR (radar)
Satellite imagery
Satellite navigation systems
Satellite observation
Satellites
Sciences of the Universe
Seismic activity
Seismic phenomena
seismic slip
Seismological data
Seismology
seismotectonics
Slip
Solifluction
Solutions
Spatial discrimination
Spatial resolution
Synthetic aperture radar
Synthetic aperture radar interferometry
Taiwan
Tectonics
Temporal resolution
Time measurement
Time series
Valleys
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Description
Summary:The Longitudinal Valley Fault (LVF) in eastern Taiwan is a high slip rate fault (about 5 cm/yr), which exhibits both seismic and aseismic slip. Deformation of anthropogenic features shows that aseismic creep accounts for a significant fraction of fault slip near the surface, whereas a fraction of the slip is also seismic, since this fault has produced large earthquakes with five Mw>6.8 events in 1951 and 2003. In this study, we analyze a dense set of geodetic and seismological data around the LVF, including campaign mode Global Positioning System(GPS) measurements, time series of daily solutions for continuous GPS stations (cGPS), leveling data, and accelerometric records of the 2003 Chenkung earthquake. To enhance the spatial resolution provided by these data, we complement them with interferometric synthetic aperture radar (InSAR) measurements produced from a series of Advanced Land Observing Satellite images processed using a persistent scatterer technique. The combined data set covers the entire LVF and spans the period from 1992 to 2010. We invert this data to infer the temporal evolution of fault slip at depth using the Principal Component Analysis‐based Inversion Method. This technique allows the joint inversion of diverse data, taking the advantage of the spatial resolution given by the InSAR measurements and the temporal resolution afforded by the cGPS data. We find that (1) seismic slip during the 2003 Chengkung earthquake occurred on a fault patch which had remained partially locked in the interseismic period, (2) the seismic rupture propagated partially into a zone of shallow aseismic interseismic creep but failed to reach the surface, and (3) that aseismic afterslip occurred around the area that ruptured seismically. We find consistency between geodetic and seismological constraints on the partitioning between seismic and aseismic creep. About 80–90% of slip on the southern section of LVF in the 0–26 km, seismogenic depth range, is actually aseismic. We infer that the clay‐rich Lichi Mélange is the key factor promoting aseismic creep at shallow depth. Key Points About 80% of slip on the LVF in the seismogenic depth range is aseismic Seismic slip during the 2003 earthquake occurred on a previously locked patch Aseismic afterslip occurred around the area that ruptured seismically
ISSN:2169-9313
2169-9356
DOI:10.1002/2013JB010603