先存俯冲陆缘背景下南海北部陆缘断陷特征及成因

庞雄; 郑金云; 梅廉夫; 柳保军; 张忠涛; 吴哲; 冯轩

doi:10.11698/PED.2021.05.19

石油勘探与开发 >

2021 , Vol. 48 >Issue 5: 1069 - 1080

DOI: https://doi.org/10.11698/PED.2021.05.19

综合研究

先存俯冲陆缘背景下南海北部陆缘断陷特征及成因

庞雄 ,
郑金云 ,
梅廉夫 ,
柳保军 ,
张忠涛 ,
吴哲 ,
冯轩

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1.中海石油（中国）有限公司深圳分公司,广东深圳 518054;
2.中海石油深海开发有限公司,广东深圳 518054;
3.中国地质大学（武汉）构造与油气资源教育部重点实验室,武汉 430074

庞雄（1962-）,男,广西玉林人,中国海洋石油总公司教授级高级工程师,长期从事珠江口盆地深水油气勘探研究。地址：广东省深圳市南山区后海滨路（深圳湾段）3168号海洋石油大厦A座,中海石油（中国）有限公司深圳分公司研究院,邮政编码：518054。E-mail: pangxiong@cnooc.com.cn

收稿日期: 2020-11-12

网络出版日期: 2021-09-17

基金资助

国家科技重大专项“大型油气田及煤层气开发”（2016ZX05026-003,2011ZX05025-003）; 中海石油有限公司科技项目（YXKY-2012-SHENHAI-01）; 中海石油（中国）有限公司“十三五”科技重点项目（CNOOC-KJ 135 ZDXM 37 SZ 01 SHENHAI）

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Characteristics and origin of continental marginal fault depressions under the background of preexisting subduction continental margin, northern South China Sea, China

PANG Xiong ,
ZHENG Jinyun ,
MEI Lianfu ,
LIU Baojun ,
ZHANG Zhongtao ,
WU Zhe ,
Feng Xuan

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1. CNOOC Ltd.-Shenzhen, Shenzhen 518054, China;
2. CNOOC Ltd.-Deepwater, Shenzhen 518054, China;
3. Faculty of Marine Science and Technology, China University of Geosciences, Wuhan 430074, China

Received date: 2020-11-12

Online published: 2021-09-17

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摘要

基于地震和钻井新资料,并综合近期相关研究成果,系统分析南海北部陆缘珠江口盆地地壳岩石圈构造和盆地结构的多样性及其复杂的发育演化过程。研究认为,珠江口盆地存在壳幔拆离、壳间拆离和上地壳内拆离3种不同构造层次的拆离断裂,不同类型的伸展拆离控制不同的盆地结构构造;位于近端带的珠一坳陷发现多个受上地壳内拆离断层控制的断陷,这些拆离断裂通常受到岩浆侵位的改造或先存断裂控制;位于超伸展区的白云凹陷—荔湾凹陷的内部结构特征差异明显,白云主洼的岩浆作用较弱,受控于壳幔拆离系,发育为宽深断陷;白云凹陷东部和西南断阶带在中始新世之后岩浆活动广泛,地壳韧性伸展变形,发育受上地壳内拆离断裂控制的宽浅断陷。对比经典的大西洋边缘岩石圈伸展破裂方式和盆地构造演化,认为中生代俯冲陆缘背景的先存构造和新生代岩浆活动是南海北部陆缘断陷结构多样化的重要控制因素。图10参28

关键词： 南海北部陆缘; 先存构造; 岩浆作用; 多层次拆离断裂; 断陷结构; 珠江口盆地

本文引用格式

庞雄 , 郑金云 , 梅廉夫 , 柳保军 , 张忠涛 , 吴哲 , 冯轩 . 先存俯冲陆缘背景下南海北部陆缘断陷特征及成因[J]. 石油勘探与开发, 2021 , 48(5) : 1069 -1080 . DOI: 10.11698/PED.2021.05.19

Abstract

Based on the new seismic and drilling data and the recent related research results, this paper systematically analyzes the diversity and complexity of evolution process of crustal lithosphere structure and basin structure in the Pearl River Mouth Basin on the northern margin of the South China Sea. Three types of detachment faults of different structural levels exist: crust-mantle detachment, inter-crust detachment and upper crust detachment. It is considered that different types of extensional detachment control different subbasin structures. Many fault depressions controlled by upper crust detachment faults have been found in the Zhu I Depression located in the proximal zone. These detachment faults are usually reformed by magma emplacement or controlled by preexisting faults. Baiyun-Liwan Sag located in the hyperextension area shows different characteristics of internal structure. The Baiyun main sag with relative weak magmatism transformation is a wide-deep fault depression, which is controlled by crust-mantle detachment system. Extensive magmatism occurred in the eastern and southwest fault steps of the Baiyun Sag after Middle Eocene, and the crust ductile extensional deformation resulted in wide-shallow fault depression controlled by the upper crust detachment fault. Based on the classical lithosphere extensional breaking and basin tectonic evolution in the Atlantic margin, it is believed that the magmatic activities and pre-existing structures in the Mesozoic subduction continental margin background are important controlling factors for the diversified continental margin faulted structures in the northern South China Sea.

Key words： northern continental margin of South China Sea; preexisting structure; magmatism; multilevel detachment faults; fault depression structure; Pearl River Mouth Basin

参考文献

[1] PATRICK U, GWENN P, GIANRETO M, et al. Hyper-extended crust in the South Atlantic: In search of a model[J]. Petroleum Geoscience, 2010, 16: 207-215.
[2] 孙珍, 刘思青, 庞雄, 等. 被动大陆边缘伸展-破裂过程研究进展[J]. 热带海洋学报, 2016, 35(1): 1-16.
SUN Zhen, LIU Siqing, PANG Xiong, et al. Recent research progress on the rifting-breakup process in passive continental margins[J]. Journal of Tropical Oceanography, 2016, 35(1): 1-16.
[3] SUTRA E G, MANATSCHAL G M. Quantification and restoration of extensional deformation along the Western Iberia and Newfoundland rifted margins[J]. Geochomistry, Geophysics, Geosystems, 2013, 14(8): 2575-2597.
[4] 庞雄, 任建业, 郑金云, 等. 陆缘地壳强烈拆离薄化作用下的油气地质特征: 以南海北部陆缘深水区白云凹陷为例[J]. 石油勘探与开发, 2018, 45(1): 27-39.
PANG Xiong, REN Jianye, ZHENG Jinyun, et al. Petroleum geology controlled by extensive detachment thinning of continental margin crust: A case study of Baiyun Sag in the deep-water area of northern South China Sea[J]. Petroleum Exploration and Development, 2018, 45(1): 27-39.
[5] 任建业, 庞雄, 雷超, 等. 被动陆缘洋陆转换带和岩石圈伸展破裂过程分析及其对南海陆缘深水盆地研究的启示[J]. 地学前缘, 2015, 22(1): 102-114.
REN Jianye, PANG Xiong, LEI Chao, et al. Ocean and continent transition in passive continental margins and analysis of lithospheric extension and breakup process: Implication for research of the deepwater basins in the continental margins of South China Sea[J]. Earth Science Frontiers, 2015, 22(1): 102-114.
[6] 任建业, 庞雄, 于鹏, 等. 南海北部陆缘深水—超深水盆地成因机制分析[J]. 地球物理学报, 2018, 61(12): 4901-4920.
REN Jianye, PANG Xiong, YU Peng, et al. Characteristics and formation machanism of deepwater and ultra-deepwater basins in the northern continental margin of the South China Sea[J]. Chinese Journal of Geophysics, 2018, 61(12): 4901-4920.
[7] YANG Linlong, REN Jianye, MCINTOSH Kirk, et al. The structure and evolution of deepwater basins in the distal margin of the northern South China Sea and their implications for the formation of the continental margin[J]. Marine and Petroleum Geology, 2018, 92: 234-254.
[8] 邹和平, 李平鲁, 饶春涛. 珠江口盆地新生代火山岩地球化学特征及其动力学意义[J]. 地球化学, 1995, 24(增刊): 33-45.
ZOU Heping, LI Pinglu, RAO Chuntao. Geochemistry of Cenozoic volcanic rocks in Pearl River Mouth Basin and its geodynamic significance[J]. Geochimica, 1995, 24(supp.): 33-45.
[9] YE Qing, MEI Lianfu, SHI Hesheng, et al. A low-angle normal fault and basement structures within the Enping Sag, Pearl River Mouth Basin: Insights into late Mesozoic to early Cenozoic tectonic evolution of the South China Sea area[J]. Tectonophysics, 2018, 731: 1-16.
[10] YE Qing, MEI Lianfu, SHI Hesheng, et al. The Late Cretaceous tectonic evolution of the South China Sea area: An overview, and new perspectives from 3D seismic reflection data[J]. Earth-Science Reviews, 2018, 187: 186-204.
[11] 郝天珧, 黄松, 徐亚, 等. 南海东北部及邻区深部结构的综合地球物理研究[J]. 地球物理学报, 2008, 51(6): 1785-1796.
HAO Tianyao, HUANG Song, XU Ya, et al. Comprehensive geophysical research on the deep structure of Northeastern South China Sea[J]. Chinese Journal of Geophysics, 2008, 51(6): 1785-1796.
[12] ZHOU Zhichao, MEI Lianfu, LIU Jun, et al. Continentward-dipping detachment fault system and asymmetric rift structure of the Baiyun Sag, northern South China Sea[J]. Tectonophysics, 2018, 726: 121-136.
[13] 张斌, 王璞珺, 张功成, 等. 珠—琼盆地新生界火山岩特征及其油气地质意义[J]. 石油勘探与开发, 2013, 40(6): 657-666.
ZHANG Bin, WANG Pujun, ZHANG Gongcheng, et al. Cenozoic volcanic rocks in the Pearl River Mouth and Southeast Hainan Basin of South China Sea and their implications for petroleum geology[J]. Petroleum Exploration and Development, 2013, 40(6): 657-666.
[14] 施和生, 杜家元, 梅廉夫, 等. 珠江口盆地惠州运动及其意义[J]. 石油勘探与开发, 2020, 47(3): 447-461.
SHI Hesheng, DU Jiayuan, MEI Lianfu, et al. Huizhou Movement and its significance in Pearl River Mouth Basin, China[J]. Petroleum Exploration and Development, 2020, 47(3): 447-461.
[15] ZHANG Cuimei, GIANRATO Manatschal, PANG Xiong, et al. Discovery of mega-sheath folds flooring the Liwan subbasin (South China Sea): Implications for the rheology of hyperextended crust[J]. Geochemmistry, Geophysics, Geosystems, 2020, 21(7): e2020GC009023.
[16] 马小丹. 珠江口盆地陆丰13构造带岩浆作用与构造关系[D]. 北京: 中国石油大学, 2016.
MA Xiaodan. The relationship between magmatic activity and tectonic structure of Lufeng 13 structural belt in Pearl River Mouth Basin[D]. Beijing: China University of Petroleum, 2016.
[17] 蔡俣. 珠江口盆地陆丰13构造断裂带特征及形成机理[D]. 北京: 中国石油大学, 2016.
CAI Yu. Characteristics and formation mechanisms of the Lufeng 13 structural belts in Pearl River Mouth Basin[D]. Beijing: China University of Petroleum, 2016.
[18] 阙晓铭, 李元森, 陈会霞, 等. 深部地幔在白云凹陷的岩浆记录: 基于BY7 火山岩的地球化学研究[J]. 华南地质与矿产, 2013, 29(2): 105-115.
QUE Xiaoming, LI Yuansen, CHEN Huixia, et al. Geochemistry research on the deep mantle activity in Baiyun Sag during the Cenozoic from the volcanic rocks of well BY7[J]. Geology and Mineral Resources of South China, 2013, 29(2): 105-115.
[19] SUN Zhen, LIN Jian, QIU Ning, et al. The role of magmatism in thinning and breakup of the South China Sea continental margin[J]. National Science Review, 2019, 6(5): 871-876.
[20] XU C H, SHl H S, BARNES C G, et al. Tracing a late Mesozoic magmatic arc along the Southeast Asian margin from the granitoids drilled from the northern south China sea[J]. International Geology Review, 2016, 58(1): 71-94.
[21] 林间, 李家彪, 徐义刚, 等. 南海大洋钻探及海洋地质与地球物理前沿研究新突破[J]. 海洋学报, 2019, 41(10): 125-140.
LIN Jian, LI Jiabiao, XU Yigang, et al. Ocean drilling and major advances in marine geological and geophysical research of the South China Sea[J]. Haiyang Xuebao, 2019, 41(10): 125-140.
[22] ZHANG C, SUN Z, MANATSCHAL G, et al. Syn-rift magmatic characteristics and evolution at a sediment-rich margin: Insights from high-resolution seismic data from the South China Sea[J]. Gondwana Research, 2021, 91(8): 81-96.
[23] LEI C, ALVES T M, REN J, et al. Depositional architecture and structural evolution of a region immediately inboard of the locus of continental breakup (Liwan Sub-basin, South China Sea)[J]. Geological Society of America Bulletin, 2019, 131(7/8): 1059-1074.
[24] ZHOU Di, WANG Wanyin, WANG Jialin, et al. Mesozoic subduction-accretion zone in northeastern South China Sea inferred from geophysical interpretations[J]. SCIENCE CHINA Earth Sciences, 2006, 49(5): 471-482.
[25] 周祖翼. 珠江口盆地的形成与南海的构造演化[J]. 海洋科学, 1993, 17(5): 62-66.
ZHOU Zuyi. Basement structure and tectonic evolution of the Pearl River Mouth Basin[J]. Marine Sciences, 1993, 17(5): 62-66.
[26] 汪品先, 翦知湣. 探索南海深部的回顾与展望[J]. 中国科学: 地球科学, 2019, 49(10): 1590-1606.
WANG Pinxian, JIAN Zhimin. Exploring the deep South China Sea: Retrospects and prospects[J]. SCIENCE CHINA Earth Sciences, 2019, 62(10): 1473-1488.
[27] WANG Pinxian, HUANG Chiyue, LIN Jian, et al. The South China Sea is not a mini-Atlantic: Plate-edge rifting vs intra-plate rifting[J]. National Science Review, 2019, 6(5): 902-913.
[28] SUTRA E, MANATSCHAL G, MOHN G, et al. Quantification and restoration of extensional deformation along the Western Iberia and Newfoundland rifted margins[J]. Geochemistry, Geophysics, Geosystems, 2013, 14(8): 2575-2597.

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