CHARACTERISTICS AND FORMATION MECHANISM OF MESO-CENOZOIC SUPERIMPOSED BASINS IN THE EAST DEPRESSION OF THE NORTH YELLOW SEA BASIN

DU Min; WANG Houjin; WANG Gaiyun; JIAN Xiaoling; WAN Xiaoming

doi:10.16562/j.cnki.0256-1492.2016.05.009

2016 Vol. 36, No. 5

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DU Min, WANG Houjin, WANG Gaiyun, JIAN Xiaoling, WAN Xiaoming. CHARACTERISTICS AND FORMATION MECHANISM OF MESO-CENOZOIC SUPERIMPOSED BASINS IN THE EAST DEPRESSION OF THE NORTH YELLOW SEA BASIN[J]. Marine Geology & Quaternary Geology, 2016, 36(5): 85-96. doi: 10.16562/j.cnki.0256-1492.2016.05.009

Citation:

DU Min, WANG Houjin, WANG Gaiyun, JIAN Xiaoling, WAN Xiaoming. CHARACTERISTICS AND FORMATION MECHANISM OF MESO-CENOZOIC SUPERIMPOSED BASINS IN THE EAST DEPRESSION OF THE NORTH YELLOW SEA BASIN[J]. Marine Geology & Quaternary Geology, 2016, 36(5): 85-96. doi: 10.16562/j.cnki.0256-1492.2016.05.009

CHARACTERISTICS AND FORMATION MECHANISM OF MESO-CENOZOIC SUPERIMPOSED BASINS IN THE EAST DEPRESSION OF THE NORTH YELLOW SEA BASIN

MLR Key Laboratory of Marine Mineral Resources, Guangzhou Marine Geological Survey, Guangzhou 510075, Guangdong, China

Received Date: 19 November 2015

Revised Date: 05 January 2016

Abstract

Abstract

Based on the latest geological-geophysical data, the faults characteristics and structural styles of the Eastern Depression of the Northern Yellow Sea Basin are studied, and the sedimentary-tectonic evolutionary stages summarized. The results show that faults in the Eastern Depression are well developed. The faults of F1 and F2 are the most important controlling ones, then followed by F9、F10、F11 and F8. The structural deformation, which is rather complex, includes the extensional, compressed, wrenching and inversed deformation. Seven sedimentary-tectonic evolutionary stages are recognized, namely the initial faulting and depressing stage(J2), the expanding stage of faults and depression (J3), the faulting and sag formation stage(K1), the tectonic inversion stage (late K1-E2), the intensive faulting and depression stage(E3), and the regional subsidence stage(N1-Q). The formation mechanism of the Eastern Depression is also discussed with reference to the regional geological background. In Middle Jurassic, the extension caused by block escape brought about the initial faulting and depression. In Late Jurassic, faulting and depressing continued and the crust became thinning due to plate subduction. In the Early Cretaceous, the Tanlu fault experienced a sinistral slip movement as the result of the change in motion of the Izanagi plate, and the faulting sag was formed in the stress field of sinistral rotation together with thermal subsidence. In Late Cretaceous, face to face subduction of plates led to compression inversion which had lasted up to the Eocene in Eastern Depression. In Oligocene, due to the re-orientation of the Pacific plate movement, the retreatment of the subduction zone and the collision of Indian and Eurasian plates, the Tanlu fault became dextral. Strong faulting and depressing of the study area has made the region a dextral transtensional tectonic setting. At the end of Oligocene, due to the increment in the subduction rate of the Pacific plate, the strengthening of Indian-Eurasian collision, and the slowing down of subduction, the inversion structures dominated again in the study area. Regional subsidence appeared again in the Eastern depression during the Miocene to Quaternary, due to thermal attenuation of lithosphere.
- structural pattern /
- tectonic evolution /
- East Depression /
- North Yellow Sea Basin

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References

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