莺歌海盆地东方区晚中新世粗粒与细粒沉积物源汇系统特征及成因分析

何小胡; 姜涛; 冯婧姿; 张亚震; 袁丙龙; 刘国昌; 何杰

doi:10.3799/dqkx.2025.251

莺歌海盆地东方区晚中新世粗粒与细粒沉积物源汇系统特征及成因分析

doi: 10.3799/dqkx.2025.251

何小胡^{1, 3, 4,},
姜涛^2, , ,,
冯婧姿²,
张亚震^{3, 4},
袁丙龙^{3, 4},
刘国昌¹,
何杰²

1.
中国石油大学(北京)油气资源与工程全国重点实验室, 北京 102249
2.
中国地质大学(武汉)海洋地质资源湖北省重点实验室, 湖北武汉 430074
3.
中海石油(中国)有限公司海南分公司, 海南海口 570312
4.
中国海油南海油气能源院士工作站, 海南海口 570312

基金项目:

国家自然科学基金项目 U25B6026

国家自然科学基金项目 42276073

国家自然科学基金项目 42202119

海南省院士创新平台科研项目 YSPTZX202302

海南省重点研发项目专项研究基金 ZDYF2024GXJS293

莺—琼盆地压溶气开发关键技术研究项目 KJRC2025A01

详细信息

作者简介:
何小胡（1982-），男，高级工程师，研究方向为南海西部石油天然气勘探综合研究与管理. E-mail：hexh@cnooc.com

通讯作者:
姜涛, ORCID：0000-0001-8845-8582. E-mail：taojiang@cug.edu.cn

中图分类号: P618
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出版历程
- 收稿日期: 2025-09-18
- 刊出日期: 2026-05-25

Characteristics and Genetic Analysis of Coarse-Grained and Fine-Grained Source-to-Sink Systems in Dongfang Area of Yinggehai Basin during Late Miocene

He Xiaohu^{1, 3, 4
,},
Jiang Tao^{2
, ,
,},
Feng Jingzi²,
Zhang Yazhen^{3, 4},
Yuan Binglong^{3, 4},
Liu Guochang¹,
He Jie²

1.
State Key Laboratory of Petroleum Resources and Engineering, China University of Petroleum (Beijing), Beijing 102249, China
2.
Hubei Key Laboratory of Marine Geological Resources, China University of Geosciences (Wuhan), Wuhan 430074, China
3.
Hainan Branch of China National Offshore Oil Corporation Limited, Haikou 570312, China
4.
CNOOC South China Sea Oil & Gas Energy Academician Workstation, Haikou 570312, China

摘要

摘要: 为了解莺歌海盆地东方区黄流组一段粗粒与细粒沉积物源汇系统的差异特征，综合运用矿物学、锆石U-Pb年代学和Sr-Nd同位素分析方法，分别对莺歌海盆地东方区黄流组一段粗粒与细粒沉积物的物源特征进行定量分析.结果表明：莺歌海盆地东方区晚中新世粗粒沉积物的红河物源平均供源占比可达约65%，越南中部物源平均供源占比约为16%，海南岛物源平均供源占比约为19%；细粒沉积物的红河物源平均供源占比约为44%，越南中部物源平均供源占比约为37%，海南岛物源平均供源占比约为19%.粗粒沉积物比细粒沉积物具有更高的红河物源和更少的越南中部物源，推测是受晚中新世青藏高原快速隆升，红河断裂反转的影响.此外，粗粒与细粒沉积物源汇系统特征的差异还受到沉积物中较低的重矿物和较高的泥质含量的影响.
- 莺歌海盆地 /
- 源汇系统 /
- 重矿物 /
- 锆石 /
- 年代学 /
- 同位素
Abstract: In order to understand the different characteristics of the source-sink system of the first member of the Huangliu Formation in the eastern part of the Yinggehai basin, the provenance characteristics of coarse-grained and fine-grained sediments in the first member of Huangliu Formation in the eastern part of Yinggehai basin were quantitatively analyzed by means of mineralogy, zircon U-Pb chronology and Sr-Nd isotope analysis. The results show that the average source proportion of the Late Miocene coarse-grained sediments in the eastern part of Yinggehai Basin can reach about 65%, with that in central Vietnam at about 16%, and that in Hainan Island at about 19%. The average source of fine sediment is about 44% in Red River, about 37% in central Vietnam and about 19% in Hainan Island. Coarse-grained sediments have higher Red River provenance and less central Vietnam provenance than fine-grained sediments, presumably due to the rapid uplift of the Qinghai-Tibet Plateau and the reversal of the Red River fault zone in the Late Miocene. Furthermore, the differences in the characteristics of the source-sink systems of coarse-grained and fine-grained sediment are also influenced by the lower content of heavy minerals and the higher content of mud in the sediments.
- Yinggehai basin /
- source-sink system /
- heavy mineral /
- zircon /
- chronology /
- isotope

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图 1 莺歌海盆地及周缘水系位置

Fig. 1. Location of the Yinggehai basin and surrounding water system

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图 2 莺歌海盆地地层系统

Fig. 2. Stratigraphic system of the Yinggehai basin

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图 3 莺歌海盆地黄流组一段重矿物组合特征

Fig. 3. Characteristics of heavy mineral association in the first member of Huangliu Formation, Yinggehai basin

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图 4 莺歌海盆地黄流组一段重矿物组合平面分布

Fig. 4. Plane distribution of heavy mineral association in Huangliu Formation, Yinggehai basin

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图 5 莺歌海盆地周缘主要现代河流河口沉积物碎屑锆石U-Pb年龄谱系

Fig. 5. Detrital zircon U-Pb age pedigree of estuarine sediments of major modern rivers in the periphery of Yinggehai basin

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图 6 莺歌海盆地黄流组一段沉积物碎屑锆石U-Pb年龄谱系

Fig. 6. U-Pb age pedigree of detrital zircon from the first member of Huangliu Formation, Yinggehai basin

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图 7 莺歌海盆地黄流组一段样品碎屑锆石U-Pb年龄基于蒙特卡洛混合模型分析结果

Fig. 7. The U-Pb age of detrital zircon from the first member of Huangliu Formation in Yinggehai basin based on the Monte Carlo model

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图 8 莺歌海盆地黄流组一段样品的各河流相对贡献

Fig. 8. The relative contribution of each river to the sample of the first section of Huangliu Formation in Yinggehai basin

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图 9 莺歌海盆地黄流组一段样品与现代潜在物源河流的碎屑锆石年龄的MDS图

Fig. 9. MDS plot of detrital zircon ages of the first member of the Huangliu Formation in Yinggehai basin and modern potential provenance rivers

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图 10 莺歌海盆地黄流组一段样品ε_Nd(0)‒⁸⁷Sr/⁸⁶Sr图解

Fig. 10. Diagram of ε_Nd(0)‒⁸⁷Sr/⁸⁶Sr of the first member of the Huangliu Formation in Yinggehai basin

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图 11 莺歌海盆地黄流组一段样品的各物源区相对贡献

Fig. 11. The relative contribution of each provenance area to the sample of the first section of Huangliu Formation in Yinggehai basin

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图 12 莺歌海盆地黄流组一段低位体系域（a）和高位体系域（b）时期沉积物模式（赵睿，2020）

Fig. 12. Depositional pattern diagrams of the lowstand (a) and highstand (b) system tracts of first section of Huangliu Formation in Yinggehai basin (Zhao, 2020)

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表 1 沉积物样品数据类型及来源

Table 1. Reference sample type and source

位置	数据类型	原始编号	来源		位置	数据类型	原始编号	来源
红河	重矿物	R5938	He et al., 2022		DF1316	Sr-Nd同位素	D1316-2	王策，2016
红河	重矿物	M5942	He et al., 2022		DF1316	Sr-Nd同位素	D1316-3	王策，2016
红河	重矿物	L5947	He et al., 2022		DF1316	Sr-Nd同位素	D1316-4	王策，2016
马江	重矿物	S6052	He et al., 2023		DF1316	Sr-Nd同位素	D1316-5	王策，2016
蓝江	重矿物	S6058	He et al., 2023		DF1316	Sr-Nd同位素	D1316-6	王策，2016
蓝江	重矿物	S6054	He et al., 2023		红河	Sr-Nd同位素	R5937	He et al., 2022
珠碧江	重矿物	2012HT01	王策等，2014		红河	Sr-Nd同位素	R5939	He et al., 2022
昌化江	重矿物	2012CH01	王策等，2014		红河	Sr-Nd同位素	R5940	He et al., 2022
北黎河	重矿物	2012DT01	王策等，2014		红河	Sr-Nd同位素	L5945	He et al., 2022
通天河	重矿物	2012TT01	王策等，2014		红河	Sr-Nd同位素	L5947	He et al., 2022
感恩河	重矿物	2012GE01	王策等，2014		红河	Sr-Nd同位素	M5942	He et al., 2022
望楼河	重矿物	2012WL01	王策等，2014		红河	Sr-Nd同位素	C5949	He et al., 2022
宁远河	重矿物	2012YC01	王策等，2014		红河	Sr-Nd同位素	D5943	He et al., 2022
红河	锆石U-Pb	527832	Fyhn et al., 2019		红河	Sr-Nd同位素	RS03	Liu et al., 2007
红河	锆石U-Pb	HUN-1	Wang et al., 2019b		红河	Sr-Nd同位素	RS11	Liu et al., 2007
红河	锆石U-Pb	Red River	Clift and Sun, 2006		红河	Sr-Nd同位素	RS16	Liu et al., 2007
红河	锆石U-Pb	RS0702	Hoang et al., 2009		红河	Sr-Nd同位素	RS23	Liu et al., 2007
红河	锆石U-Pb	VN05060801	Hoang et al., 2009		红河	Sr-Nd同位素	RS26	Liu et al., 2007
红河	锆石U-Pb	VN07060501	Hoang et al., 2009		红河	Sr-Nd同位素	RS32	Liu et al., 2007
红河	锆石U-Pb	WHT-1	Wang et al., 2019b		红河	Sr-Nd同位素	RS35	Liu et al., 2007
红河	锆石U-Pb	VN05061101	Hoang et al., 2009		红河	Sr-Nd同位素	VN05060701	Clift et al., 2008
红河	锆石U-Pb	BLR-1	Wang et al., 2019b		红河	Sr-Nd同位素	VN05060702	Clift et al., 2008
马江	锆石U-Pb	527831	Fyhn et al., 2019		红河	Sr-Nd同位素	VN05060703	Clift et al., 2008
马江	锆石U-Pb	MA-1	Wang et al., 2019b		红河	Sr-Nd同位素	VN05060704	Clift et al., 2008
蓝江	锆石U-Pb	527830	Fyhn et al., 2019		红河	Sr-Nd同位素	VN05060705	Clift et al., 2008
蓝江	锆石U-Pb	CA-1	Wang et al., 2019b		红河	Sr-Nd同位素	VN05060706	Clift et al., 2008
蓝江	锆石U-Pb	M03-21B	Usuki et al., 2013		红河	Sr-Nd同位素	VN05060707	Clift et al., 2008
蓝江	锆石U-Pb	M03-24B	Usuki et al., 2013		红河	Sr-Nd同位素	VN05060710	Clift et al., 2008
宋河	锆石U-Pb	12061704	Jonell et al., 2017		红河	Sr-Nd同位素	VN05060801	Clift et al., 2008
宋河	锆石U-Pb	12061703	Jonell et al., 2017		红河	Sr-Nd同位素	VN05060802	Clift et al., 2008
宋河	锆石U-Pb	12061711	Jonell et al., 2017		红河	Sr-Nd同位素	VN05060804	Clift et al., 2008
宋河	锆石U-Pb	12061712	Jonell et al., 2017		红河	Sr-Nd同位素	VN05060805	Clift et al., 2008
宋河	锆石U-Pb	14052801	Jonell et al., 2017		红河	Sr-Nd同位素	VN05060806	Clift et al., 2008
宋河	锆石U-Pb	12061801	Jonell et al., 2017		红河	Sr-Nd同位素	VN05060807	Clift et al., 2008
宋河	锆石U-Pb	14052705	Jonell et al., 2017		红河	Sr-Nd同位素	VN05060808	Clift et al., 2008
宋河	锆石U-Pb	12061807	Jonell et al., 2017		红河	Sr-Nd同位素	VN05060809	Clift et al., 2008
宋河	锆石U-Pb	12061804	Jonell et al., 2017		红河	Sr-Nd同位素	VN05061101	Clift et al., 2008
珠碧江	锆石U-Pb	HL5	Gong et al., 2021		红河	Sr-Nd同位素	H1	Duan et al., 2023
珠碧江	锆石U-Pb	2012HT01	Wang et al., 2015		红河	Sr-Nd同位素	H2	Duan et al., 2023
昌化江	锆石U-Pb	HL4	Gong et al., 2021		红河	Sr-Nd同位素	H8	Duan et al., 2023
昌化江	锆石U-Pb	2012CH01	Wang et al., 2015		红河	Sr-Nd同位素	H9	Duan et al., 2023
昌化江	锆石U-Pb	2012CH02	Wang et al., 2015		红河	Sr-Nd同位素	H12	Duan et al., 2023
北黎河	锆石U-Pb	2012DT01	Wang et al., 2015		红河	Sr-Nd同位素	H15	Duan et al., 2023
感恩河	锆石U-Pb	2012GE01	Wang et al., 2015		红河	Sr-Nd同位素	H16	Duan et al., 2023
望楼河	锆石U-Pb	2012WL01	Wang et al., 2015		红河	Sr-Nd同位素	H19	Duan et al., 2023
宁远河	锆石U-Pb	NY-02	Chen et al., 2022		红河	Sr-Nd同位素	H20	Duan et al., 2023
宁远河	锆石U-Pb	2012YC01	Wang et al., 2015		红河	Sr-Nd同位素	H22	Duan et al., 2023
L11	锆石U-Pb	L11-5	Wang et al., 2019a		红河	Sr-Nd同位素	H24	Duan et al., 2023
L262	锆石U-Pb	L262-1	Wang et al., 2015		红河	Sr-Nd同位素	H28	Duan et al., 2023
LO	锆石U-Pb	LO-9	Wang et al., 2019b		红河	Sr-Nd同位素	H29	Duan et al., 2023
LO	锆石U-Pb	LH1	Jiang et al., 2015		红河	Sr-Nd同位素	H30	Duan et al., 2023
DF1112	锆石U-Pb	DF1112-2	Wang et al., 2014		红河	Sr-Nd同位素	H34	Duan et al., 2023
DF1312	锆石U-Pb	DF1312-9R	Wang et al., 2014		红河	Sr-Nd同位素	H35	Duan et al., 2023
DF1312	锆石U-Pb	DF13	Cao et al., 2015		红河	Sr-Nd同位素	H39	Duan et al., 2023
DF1313	锆石U-Pb	DF1313-4R	Wang et al., 2014		红河	Sr-Nd同位素	Su2	Duan et al., 2023
HK29	锆石U-Pb	H2912-2	王策，2016		红河	Sr-Nd同位素	Su3	Duan et al., 2023
HK30	锆石U-Pb	H3031A-3	王策，2016		红河	Sr-Nd同位素	Su4	Duan et al., 2023
LO	Sr-Nd同位素	L1X-6	王策，2016		红河	Sr-Nd同位素	Su5	Duan et al., 2023
LO	Sr-Nd同位素	L1X-7	王策，2016		红河	Sr-Nd同位素	Su7	Duan et al., 2023
LO	Sr-Nd同位素	L1X-8	王策，2016		红河	Sr-Nd同位素	Su12	Duan et al., 2023
DF1112	Sr-Nd同位素	D1112-1	王策，2016		红河	Sr-Nd同位素	Su16	Duan et al., 2023
DF1112	Sr-Nd同位素	D1112-2	王策，2016		红河	Sr-Nd同位素	Su17	Duan et al., 2023
DF1112	Sr-Nd同位素	D1112-3	王策，2016		红河	Sr-Nd同位素	Su18	Duan et al., 2023
DF1112	Sr-Nd同位素	D1112-4	王策，2016		红河	Sr-Nd同位素	Su19	Duan et al., 2023
DF1312	Sr-Nd同位素	D1312-1	王策，2016	马江	Sr-Nd同位素	S6052	He et al., 2023
DF1312	Sr-Nd同位素	D1312-2	王策，2016	蓝江	Sr-Nd同位素	S6054	He et al., 2023
DF1312	Sr-Nd同位素	D1312-3	王策，2016	蓝江	Sr-Nd同位素	S6058	He et al., 2023
DF1312	Sr-Nd同位素	D1312-4	王策，2016	昌化江	Sr-Nd同位素	CH02	Wan et al., 2015
DF1316	Sr-Nd同位素	D1316-1	王策，2016

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表 2 莺歌海盆地黄流组一段井样品各物源占比

Table 2. Source proportion of samples from well 1 of Huangliu Formation in Yinggehai basin

数据来源	井名	取样平均深度（m）	层位	岩性	取样部位	红河物源含量	越南中部物源含量	海南岛物源含量
本研究	DF1313	2 910.25	黄一段	泥岩/泥质粉砂岩	块状泥岩	0.41	0.42	0.18
本研究	DF1314	2 870.00	黄一段	泥岩/泥质粉砂岩	块状粉砂岩	0.44	0.35	0.21
本研究	DF13110	2 914.46	黄一段	泥岩/泥质粉砂岩	块状粉砂岩	0.34	0.48	0.18
本研究	DF1322	3 067.60	黄一段	泥岩/泥质粉砂岩	泥质条带	0.38	0.40	0.21
本研究	DF1328D	3 092.00	黄一段	泥岩/泥质粉砂岩	块状粉砂岩	0.34	0.39	0.26
本研究	DF1127	2 779.50	黄一段	泥岩/泥质粉砂岩	泥质条带	0.36	0.46	0.19
王策（2016）	DF1112	2 682.50	黄一段	泥质细砂岩/细砂岩	全岩	0.55	0.31	0.15
王策（2016）	DF1312	3 053.75	黄一段	粉细砂岩/粉砂泥岩	全岩	0.55	0.30	0.15
王策（2016）	DF1316	2 872.00	黄一段	细砂岩/粉细砂岩 /岩屑泥	全岩	0.59	0.26	0.15

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