Chow Son Chen scite author profile

Chow Son Chen

5Publications

70Citation Statements Received

103Citation Statements Given

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131

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National Central University

Publications

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The Deep Electrical Structure of Southern Taiwan and Its Tectonic Implications

Chiang¹,

Chen²,

Unsworth³

et al. 2010

Terr. Atmos. Ocean. Sci.

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The Taiwan orogen has formed as a result of the arc-continent collision between the Eurasian continental margin and the Luzon volcanic arc over the last 5 million years and is the type example of an arc-continent collision. The tectonic processes at work beneath Taiwan are still debated; the available data have been interpreted with both thin-skinned and lithospheric collision models. In 2004, the Taiwan Integrated Geodynamical Research (TAIGER) project began a systematic investigation of the crustal and upper mantle structure beneath Taiwan. TAIGER magnetotelluric (MT) data from central Taiwan favor a thick-skinned model for that region. The Taiwan orogen becomes younger to the south, so the earlier stages of collision were investigated with a 100-km-long MT profile in southern Taiwan at latitude of 23.3°N. Data were recorded at 15 MT sites and tensor decomposition and two-dimensional inversion were applied to the MT data. The shallow electrical resistivity structure is in good agreement with surface geology. The deeper structure shows a major conductor in the mid-crust that can be explained by fluid content of 0.4 -1.4%. A similar feature was observed in central Taiwan, but with a higher fluid content. The conductor in southern Taiwan extends to lower crustal depths and is likely caused by fluids generated by metamorphic reactions in a thickened crust. Together the central and southern Taiwan MT profiles show a crustal root beneath the Central Range.

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Marine controlled source electromagnetic method used for the gas hydrate investigation in the offshore area of SW Taiwan

Hsu

Chiang

Evans

et al. 2014

Journal of Asian Earth Sciences

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Evaluating the Chingshui geothermal reservoir in northeast Taiwan with a 3D integrated geophysical visualization model

Chang

Song

et al. 2014

Geothermics

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Sanyi‐Puli conductivity anomaly in NW Taiwan and its implication for the tectonics of the 1999 Chi‐Chi earthquake

Chen

2002

Geophysical Research Letters

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Based on tensor decomposition technique, we have analyzed the dimensionality of magnetotelluric (MT) data and propose a 2‐D electrical model characterized by a high conductive anomaly beneath Sanyi‐Puli seismic zone, a distinct NW‐SE trending linear seismic zone in the fold‐thrust belt of NW Taiwan. Fluid pressurization indicated by the highly conductive anomaly may result in the active seismicity in Sanyi‐Puli seismic zone and, particularly, may also induce the large slip associated with high static stress drop in the northern part of the fault rupture process for the 1999 Chi‐Chi, Taiwan, earthquake.

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Fault Zone Resistivity Structure and Monitoring at the Taiwan Chelungpu Drilling Project (TCDP)

Chiang¹,

Unsworth²,

Chen³

et al. 2008

Terr. Atmos. Ocean. Sci.

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The Taiwan Chelungpu-fault drilling project (TCDP) has undertaken scientific drilling and directly sampled the sub-surface rupture of the 1999 Chi-Chi earthquake. Audio-magnetotelluric (AMT) measurements were used to investigate electrical resistivity structure at the TCDP site from 2004 -2006. These data show a geoelectric strike direction of N15°E to N30°E. Inversion and forward modeling of the AMT data were used to generate a 1-D resistivity model that has a prominent low resistivity zone (< 10 ohm-m) between depths of 1100 and 1500 m. When combined with porosity measurements, the AMT measurements imply that the ground water has a resistivity of 0.55 ohm-m at the depth of the fault zone.Time variations in the measured AMT data were observed from 2004 -2005 with maximum changes of 43% in apparent resistivity and 18°in phase. The change in apparent resistivity is greatest in the 1000 -100 Hz frequency band. These frequencies are sensitive to the resistivity structure of the upper 500 m of the hanging wall of the Chelungpu Fault. The decrease in resistivity over time appears to be robust and could be caused by an increase in porosity and a re-distribution of the groundwater.

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Chow Son Chen

The Deep Electrical Structure of Southern Taiwan and Its Tectonic Implications

Marine controlled source electromagnetic method used for the gas hydrate investigation in the offshore area of SW Taiwan

Evaluating the Chingshui geothermal reservoir in northeast Taiwan with a 3D integrated geophysical visualization model

Sanyi‐Puli conductivity anomaly in NW Taiwan and its implication for the tectonics of the 1999 Chi‐Chi earthquake

Fault Zone Resistivity Structure and Monitoring at the Taiwan Chelungpu Drilling Project (TCDP)

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