The gradual subduction-collision evolution model of Proto-South China Sea and its control on oil and gas

Xiaojun Xie; Wu Tang; Gongcheng Zhang; Zhigang Zhao; Shuang Song; Shixiang Liu; Yibo Wang; Jia Guo

doi:10.1007/s13131-022-2132-z

Volume 42 Issue 3

Mar. 2023

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Xiaojun Xie, Wu Tang, Gongcheng Zhang, Zhigang Zhao, Shuang Song, Shixiang Liu, Yibo Wang, Jia Guo. The gradual subduction-collision evolution model of Proto-South China Sea and its control on oil and gas[J]. Acta Oceanologica Sinica, 2023, 42(3): 123-137. doi: 10.1007/s13131-022-2132-z

Citation:

Xiaojun Xie, Wu Tang, Gongcheng Zhang, Zhigang Zhao, Shuang Song, Shixiang Liu, Yibo Wang, Jia Guo. The gradual subduction-collision evolution model of Proto-South China Sea and its control on oil and gas[J]. Acta Oceanologica Sinica, 2023, 42(3): 123-137. doi: 10.1007/s13131-022-2132-z

Citation:

Xiaojun Xie, Wu Tang, Gongcheng Zhang, Zhigang Zhao, Shuang Song, Shixiang Liu, Yibo Wang, Jia Guo. The gradual subduction-collision evolution model of Proto-South China Sea and its control on oil and gas[J]. Acta Oceanologica Sinica, 2023, 42(3): 123-137. doi: 10.1007/s13131-022-2132-z

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The gradual subduction-collision evolution model of Proto-South China Sea and its control on oil and gas

doi: 10.1007/s13131-022-2132-z

China National Offshore Oil Corporation (CNOOC) Research Institute Co., Ltd., Beijing 100028, China

Funds: The National Natural Science Foundation of China under contract No. 91528303; the National Science and Technology Major Project under contract No. 2016ZX05026-004; the CNOOC Basic Geology and Exploration Strategy of Natural Gas in the South China Sea under contract No. 2021-KT-YXKY-05.

More Information

Corresponding author: zhanggch@cnooc.com.cn
Received Date: 2022-02-23
Accepted Date: 2022-11-15

Available Online: 2023-01-10

Publish Date: 2023-03-25

Abstract

Abstract

This study involved outcrop, drilling, seismic, gravity, and magnetic data to systematically document the geological records of the subduction process of Proto-South China Sea (PSCS) and establish its evolution model. The results indicate that a series of arc-shaped ophiolite belts and calcalkaline magmatic rocks are developed in northern Borneo, both of which have the characteristics of gradually changing younger from west to east, and are direct signs of subduction and collision of PSCS. At the same time, the subduction of PSCS led to the formation of three accretion zones from the south to the north in Borneo, the Kuching belt, Sibu belt, and Miri belt. The sedimentary formation of northern Borneo is characterized by a three-layer structure, with the oceanic basement at the bottom, overlying the deep-sea flysch deposits of the Rajang–Crocker group, and the molasse sedimentary sequence that is dominated by river-delta and shallow marine facies at the top, recording the whole subduction–collision–orogeny process of PSCS. Further, seismic reflection and tomography also confirmed the subduction and collision of PSCS. Based on the geological records of the subduction and collision of PSCS, combined with the comprehensive analysis of segmented expansion and key tectonic events in the South China Sea, we establish the “gradual” subduction-collision evolution model of PSCS. During the late Eocene to middle Miocene, the Zengmu, Nansha, and Liyue–Palawan blocks were separated by West Baram Line and Balabac Fault, which collided with the Borneo block and Kagayan Ridge successively from the west to the east, forming several foreland basin systems, and PSCS subducted and closed from the west to the east. The subduction and extinction of PSCS controlled the oil and gas distribution pattern of southern South China Sea (SSCS) mainly in three aspects. First, the “gradual” closure process of PSCS led to the continuous development of many large deltas in SSCS. Second, the deltas formed during the subduction–collision of PSCS controlled the development of source rocks in the basins of SSCS. Macroscopically, the distribution and scale of deltas controlled the distribution and scale of source rocks, forming two types of source rocks, namely, coal measures and terrestrial marine facies. Microscopically, the difference of terrestrial higher plants carried by the delta controlled the proportion of macerals of source rocks. Third, the difference of source rocks mainly controlled the distribution pattern of oil and gas in SSCS. Meanwhile, the difference in the scale of source rocks mainly controlled the difference in the amount of oil and gas discoveries, resulting in a huge amount of oil and gas discoveries in the basin of SSCS. Meanwhile, the difference of macerals of source rocks mainly controlled the difference of oil and gas generation, forming the oil and gas distribution pattern of “nearshore oil and far-shore gas”.
- Proto-South China Sea,
- gradual subduction-collision,
- evolution model,
- oil and gas distribution,
- southern South China Sea,
- Borneo

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References(74)

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