Your search keyword '"Tsai, Ching-Hui"' showing total 6 results

1. Shallow gas hydrates off southwest Taiwan and their mechanisms

Author

Huang, Yin-Sheng, primary, Hsu, Shu-Kun, additional, Su, Chih-Chieh, additional, Lin, Andrew Tien-Shun, additional, Yu, Pai-Sen, additional, Babonneau, Nathalie, additional, Ratzov, Gueorgui, additional, Lallemand, Serge, additional, Huang, Pi-Chuen, additional, Lin, Shiao-Shan, additional, Lin, Jing-Yi, additional, Wei, Kuo-Yen, additional, Chang, Yuan-Pin, additional, Yu, Neng-Ti, additional, and Tsai, Ching-Hui, additional

Published

2021

2. Age and tectonic evolution of the northwest corner of the West Philippine Basin

Author

Doo, Wen-Bin, primary, Hsu, Shu-Kun, additional, Yeh, Yi-Ching, additional, Tsai, Ching-Hui, additional, and Chang, Ching-Ming, additional

Published

2014

3. Age and tectonic evolution of the northwest corner of the West Philippine Basin.

Author

Doo, Wen-Bin, Hsu, Shu-Kun, Yeh, Yi-Ching, Tsai, Ching-Hui, and Chang, Ching-Ming

Subjects

SEA-floor spreading, OCEAN bottom, SUBMARINE fracture zones, SUBMARINE geology, GEOLOGICAL basins

Abstract

To understand the tectonic characteristics and age of the northwestern part of the West Philippine Basin (WPB), multi-beam bathymetry and geomagnetic data have been collected and analyzed. The seafloor morphology obviously shows NW-SE trending seafloor fabrics and NE-SW trending fracture zones, indicating a NE-SW seafloor spreading direction. An overlapping spreading center near 22°20′N and 125°E is identified. Besides, numerous seamounts indicate an excess supply of magma during or after the oceanic crust formation. A V-shaped seamount chain near 21°52′N and 124°26′E indicates a southeastward magma propagation and also indicates the location of the seafloor spreading ridge. On the basis of the newly collected geomagnetic data, the magnetic anomaly shows NW-SE trending magnetic lineations. Both bathymetry and geomagnetic data reveal NE-SW seafloor spreading features between the Gagua Ridge and the Luzon Okinawa fracture zone (LOFZ). Our magnetic age modeling indicates that the age of the northwestern corner of the WPB west of the LOFZ is between 47.5 to 54 Ma (without including overlapping spreading center), which is linked to the first spreading phase of the WPB to the east of the LOFZ. In addition, the age of the Huatung Basin is identified to be between 33 to 42 Ma, which is similar to the second spreading phase of the WPB. [ABSTRACT FROM AUTHOR]

Published

2015

4. Gas seepage, pockmarks and mud volcanoes in the near shore of SW Taiwan.

Author

Chen, Song-Chuen, Hsu, Shu-Kun, Tsai, Ching-Hui, Ku, Chia-Yen, Yeh, Yi-Ching, and Wang, Yunshuen

Subjects

GAS seepage, GAS hydrates, VOLCANOES, SIDESCAN sonar, OCEAN bottom, BACKSCATTERING, SEISMIC reflection method

Abstract

In order to understand gas hydrate related seafloor features in the near shore area off SW Taiwan, a deep-towed sidescan sonar and sub-bottom profiler survey was conducted in 2007. Three profiles of high-resolution sub-bottom profiler reveal the existence of five gas seeps (G96, GS1, GS2, GS3 and GS4) and one pockmark (PM) in the study area. Gas seeps and pockmark PM are shown in lines A and C, while no gas venting feature is observed along line B. This is the first time that a gas-hydrate related pockmark structure has been imaged off SW Taiwan. The relatively high backscatter intensity in our sidescan sonar images indicates the existence of authigenic carbonates or chemosynthetic communities on the seafloor. More than 2,000 seafloor photos obtained by a deep-towed camera (TowCam) system confirm the relatively high backscatter intensity of sidescan sonar images related to bacteria mats and authigenic carbonates formation at gas seep G96 and pockmark PM areas. Water column gas flares are observed in sidescan sonar images along lines A and C. Likewise, EK500 echo sounder images display the gas plumes above gas seep G96, pockmark PM and gas seep GS1; the gas plumes heights reach about 150, 100 and 20 m from seafloor, respectively. Based on multichannel seismic reflection (MCS) profiles, an anticline structure trending NNE-SSW is found beneath gas seep G96, pockmark PM and gas seep GS2. It implies that the gas venting features are related to the anticline structure. A thermal fluid may migrate from the anticline structure to the ridge crest, then rises up to the seafloor along faults or fissures. The seafloor characteristics indicate that the gas seep G96 area may be in a transitional stage from the first to second stage of a gas seep self-sealing process, while the pockmark PM area is from the second to final stage. In the pockmark PM area, gas venting is observed at eastern flank but not at the bottom while authigenic carbonates are present underneath the pockmark. It implies that the fluid migration pathways could have been clogged by carbonates at the bottom and the current pathway has shifted to the eastern flank of the pockmark during the gas seep self-sealing process. [ABSTRACT FROM AUTHOR]

Published

2010

5. Crustal Thinning of the Northern Continental Margin of the South China Sea.

Author

Tsai, Ching-Hui, Hsu, Shu-Kun, Yeh, Yi-Ching, Lee, Chao-Shing, and Xia, Kanyuan

Abstract

Magnetic data suggest that the distribution of the oceanic crust in the northern South China Sea (SCS) may extend to about 21 °N and 118.5 °E. To examine the crustal features of the corresponding continent–ocean transition zone, we have studied the crustal structures of the northern continental margin of the SCS. We have also performed gravity modeling by using a simple four-layer crustal model to understand the geometry of the Moho surface and the crustal thicknesses beneath this transition zone. In general, we can distinguish the crustal structures of the study area into the continental crust, the thinned continental crust, and the oceanic crust. However, some volcanic intrusions or extrusions exist. Our results indicate the existence of oceanic crust in the northernmost SCS as observed by magnetic data. Accordingly, we have moved the continent–ocean boundary (COB) in the northeastern SCS from about 19 °N and 119.5 °E to 21 °N and 118.5 °E. Morphologically, the new COB is located along the base of the continental slope. The southeastward thinning of the continental crust in the study area is prominent. The average value of crustal thinning factor of the thinned continental crust zone is about 1.3–1.5. In the study region, the Moho depths generally vary from ca. 28 km to ca. 12 km and the crustal thicknesses vary from ca. 24 km to ca. 6 km; a regional maximum exists around the Dongsha Island. Our gravity modeling has shown that the oceanic crust in the northern SCS is slightly thicker than normal oceanic crust. This situation could be ascribed to the post-spreading volcanism or underplating in this region. [ABSTRACT FROM AUTHOR]

Published

2004

6. New Bathymetry and Magnetic Lineations Identifications in the Northernmost South China Sea and their Tectonic Implications.

Author

Hsu, Shu-Kun, Yeh, Yi-ching, Doo, Wen-Bin, and Tsai, Ching-Hui

Abstract

The seafloor spreading of the South China Sea (SCS) was previously believed to take place between ca. 32 and 15 Ma (magnetic anomaly C11 to C5c). New magnetic data acquired in the northernmost SCS however suggests the existence of E–W trending magnetic polarity reversal patterns. Magnetic modeling demonstrates that the oldest SCS oceanic crust could be Late Eocene (as old as 37 Ma, magnetic anomaly C17), with a half-spreading rate of 44 mm/yr. The new identified continent–ocean boundary (COB) in the northern SCS generally follows the base of the continental slope. The COB is also marked by the presence of a relatively low magnetization zone, corresponding to the thinned portion of the continental crust. We suggest that the northern extension of the SCS oceanic crust is terminated by an inactive NW–SE trending trench-trench transform fault, called the Luzon–Ryukyu Transform Plate Boundary (LRTPB). The LRTPB is suggested to be a left-lateral transform fault connecting the former southeast-dipping Manila Trench in the south and the northwest-dipping Ryukyu Trench in the north. The existence of the LRTPB is demonstrated by the different patterns of the magnetic anomalies as well as the different seafloor morphology and basement relief on both sides of the LRTPB. Particularly, the northwestern portion of the LRTPB is marked by a steep northeast-dipping escarpment, along which the Formosa Canyon has developed. The LRTPB probably became inactive at ca. 20 Ma while the former Manila Trench prolonged northeastwards and connected to the former Ryukyu Trench by another transform fault. This reorganization of the plate boundaries might cause the southwestern portion of the former Ryukyu Trench to become extinct and a piece of the Philippine Sea Plate was therefore trapped amongst the LRTPB, the Manila Trench and the continental margin. [ABSTRACT FROM AUTHOR]

Published

2004