https://scholars.lib.ntu.edu.tw/handle/123456789/302928
Title: | Tectonic wedging along the rear of the offshore Taiwan accretionary prism | Authors: | Chi, Wu-Cheng Reed, Donald L. Moore, Greg Nguyen, Tuan CHAR-SHINE LIU Lundberg, Neil |
Keywords: | Gravity modeling; Lithospheric collision; Seismic reflection data; Tectonic wedge | Issue Date: | 2003 | Journal Volume: | 374 | Journal Issue: | 3-4 | Start page/Pages: | 199-217 | Source: | Tectonophysics | Abstract: | The structural geometry, kinematics and density structure along the rear of the offshore Taiwan accretionary prism were studied using seismic reflection profiling and gravity modeling. Deformation between the offshore prism and forearc basin at the point of incipient collision, and southward into the region of subduction, has been interpreted as a tectonic wedge, similar to those observed along the front of mountain ranges. This tectonic wedge is bounded by an east-dipping roof thrust and a blind, west-dipping floor thrust. An east-dipping sequence of forearc-basin strata in the hanging wall of the roof thrust reaches a thickness in excess of 4 km near the tip of the interpreted tectonic wedge. Section restoration of the roof sequence yields an estimate of 4 km of shortening, which is small compared with that inferred in the collision area to the north, based on the variation in distance between the apex of the prism and the island arc. Previous studies propose that either high-angle normal faulting or backfolding has exhumed the metamorphic rocks along the eastern flank of the Central Range in the collision zone on land. To better constrain the initial crustal configuration, we tested 350 crustal models to fit the free-air gravity anomaly data in the offshore region to study the density structure along the rear of the accretionary prism in the subduction and initial collision zones before the structures become more complex in the collision zone on land. The gravity anomaly, observed in the region of subduction (20.2°N), can be modeled with the arc basement forming a trenchward-dipping backstop that is overlain by materials with densities in the range of sedimentary rocks. Near the point of incipient collision (20.9°N), however, the free-air gravity anomaly over the rear of the prism is approximately 40 mgal higher, compared with the region of subduction, and requires a significant component of high density crustal rocks within the tectonic wedge. These results suggest that the forearc basement may be deformed along the rear of the prism, associated with the onset of collision, but not in the subduction region further to the south. © 2003 Elsevier B.V. All rights reserved. |
URI: | http://www.scopus.com/inward/record.url?eid=2-s2.0-0142168369&partnerID=MN8TOARS http://scholars.lib.ntu.edu.tw/handle/123456789/302928 |
DOI: | 10.1016/j.tecto.2003.08.004 | SDG/Keyword: | accretionary prism; collision; deformation; gravity anomaly; lithosphere; seismic reflection; tectonic wedge; South China Sea; Taiwan |
Appears in Collections: | 海洋研究所 |
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