底流与重力流交互作用下的朵体沉积特征: 以东非鲁伍马盆地中新统为例<sup>&#x0002A;</sup>

doi:10.7605/gdlxb.2024.00.054

古地理学报 ›› 2024, Vol. 26 ›› Issue (4): 1005-1016. doi: 10.7605/gdlxb.2024.00.054

所属专题：深水沉积学专辑；

• 深水沉积专题 • 上一篇

底流与重力流交互作用下的朵体沉积特征: 以东非鲁伍马盆地中新统为例^*

刘钰星^1,2,3,4, 陈宇航^1,2,3,4, 范国章⁵, 李林⁵, 鲁银涛⁵, 左国平⁵, 曹全斌⁵, 丁群峰^1,2,3

1 西安石油大学地球科学与工程学院,陕西西安 710065;
2 西安石油大学陕西省油气成藏地质学重点实验室,陕西西安 710065;
3 自然资源部海底科学重点实验室,浙江杭州 310012;
4 西安石油大学西安市致密油(页岩油)开发重点实验室,陕西西安 710065;
5 中国石油杭州地质研究院,浙江杭州 310023

收稿日期:2023-08-31 修回日期:2024-01-17 出版日期:2024-08-01 发布日期:2024-07-29
通讯作者: 陈宇航,男,1988年生,博士、副教授,主要从事海洋油气勘探、深水沉积研究。E-mail: cyh@xsyu.edu.cn。
作者简介:刘钰星,女,1999年生,硕士研究生,主要从事深水沉积研究。E-mail: yuxing0301@163.com。
基金资助:
*自然资源部海底科学重点实验室开放基金(编号: KLSG2208)、国家自然科学基金(编号: 41802128,42076219)、陕西省自然科学基础研究计划(编号: 2024JC-YBMS-227)和西安石油大学研究生创新与实践能力培养计划(编号: YCS23113049)联合资助

Sedimentary characteristics of lobes formed by interacting bottom currents and gravity flows: a case study from the Miocene in Rovuma Basin,East Africa

LIU Yuxing^1,2,3,4, CHEN Yuhang^1,2,3,4, FAN Guozhang⁵, LI Lin⁵, LU Yintao⁵, ZUO Guoping⁵, CAO Quanbin⁵, DING Qunfeng^1,2,3

1 School of Earth Sciences and Engineering,Xi'an Shiyou University,Xi'an 710065,China;
2 Shaanxi Key Laboratory of Petroleum Accumulation Geology,Xi'an Shiyou University,Xi'an 710065,China;
3 Key Laboratory of Submarine Geosciences,Ministry of Natural Resources,Hangzhou 310012,China;
4 Xi'an Key Laboratory of Tight Oil(Shale Oil)Development,Xi'an Shiyou University,Xi'an 710065,China;
5 PetroChina Hangzhou Institute of Geology,Hangzhou 310023,China

Received:2023-08-31 Revised:2024-01-17 Online:2024-08-01 Published:2024-07-29
Contact: CHEN Yuhang,born in 1988,Ph.D.,is an associate professor. He is mainly engaged in offshore oil and gas exploration and deep-water sedimentation. E-mail: cyh@xsyu.edu.cn.
About author:LIU Yuxing,born in 1999,is a master's degree candidate. She is mainly engaged in deep-water sedimentation research. E-mail: yuxing0301@163.com.
Supported by:
Co-funded by the Open Fund of the Key Laboratory of Submarine Science of Ministry of Natural Resources(No. KLSG2208)、the National Natural Science Foundation of China(Nos. 41802128,42076219)、 the Natural Science Foundation of Shaanxi Province of China(No.2024JC-YBMS-227)and the Postgraduate Innovation and Practice Ability Development Fund of Xi'an Shiyou University(No. YCS23113049)

摘要/Abstract

摘要： 底流与重力流的交互作用是重要的深水沉积作用类型,对海底沉积物再分配及海底地貌改造具有重要控制作用。目前对底流与水道中重力流的交互作用研究较成熟,但对底流影响下朵体的沉积特征研究较少。本研究以东非鲁伍马盆地古近系中新统朵体为目标,综合利用三维地震和测井资料,通过地震相和地震属性分析,确定朵体分布及内部岩性特征。在定量恢复重力流流速基础上,结合区域洋流资料,揭示底流与重力流交互作用对朵体沉积的控制作用。结果表明受向北流动的底流影响,早期水道向南迁移,北侧天然堤发育,在水道南侧形成负向地形,导致后期朵体沉积于水道南侧。底流作用下的朵体沉积特征受底流和朵体内重力流流向的影响。当底流与朵体延伸方向相反且斜交时,由于重力流流速远大于底流,朵体在逆底流流向一翼(南侧),重力流与底流流向几乎相反,底流影响被抑制,朵体从轴部向末端逐渐变薄,泥质含量增加; 在顺底流流向一翼(北侧),重力流方向与底流斜交,重力流顶部泥质被底流淘洗出去,朵体以砂质沉积为主。当底流与重力流流向接近正交时,朵体受底流影响整体上一致,重力流顶部泥质被淘洗,逆底流流向一翼朵体以厚层砂质沉积为主,向顺底流流向一翼砂体厚度减小、泥质含量增加。

关键词: 底流, 重力流, 交互作用, 朵体, 鲁伍马盆地

Abstract: The interplay of bottom currents and gravity flows is an important deep-water sedimentary process,which plays an important role in redistributing submarine sediments and reshaping seafloor bedforms. At present,research on bottom currents and gravity flows interaction in deep-water channels is relatively mature,but little work has been done on the sedimentary characteristics of lobes influenced by bottom currents. Based on an integrated study of seismic facies and seismic attributes using 3D seismic and logging data,this study documents the distribution and lithological characteristics of the Miocene lobes in the Rovuma Basin(East Africa). The effect of bottom currents and gravity flows interaction on lobe sedimentation is revealed through quantitative restoration of gravity flow velocity,combined with regional ocean current data analysis. The results indicate that,early channels migrated southward due to the northward-directed bottom current,and their northern levees are well developed with a negative terrain present to the south of the channels,which led subsequent lobes to deposit to the south of these channels. Deposition of the lobes is influenced by bottom current flow direction and gravity flows forming the lobes. Velocity of the gravity flows is much higher than that of the bottom currents. Therefore,when the directions of bottom currents and the lobe propogation are opposite and oblique,the influence of bottom currents is suppressed on the side against bottom current flow direction(south side),and the lobe gradually thins from the axis to the margin,accompanied by increasing mud content;On the side downstream of bottom current flow direction(north side),gravity flows intersect obliquely with bottom currents,and the mud at the top of turbidity currents is stripped off by the bottom current,leaving sand deposited in the lobe. When bottom current flow direction and lobe propogration direction are close to orthogonal,the influence of bottom current on the lobe is consistent on the whole,and the mud at the top of gravity flows is stripped. Therefore,the lobe is mainly composed of thick sandy deposits at the side against the bottom current flow direction,and the sand content decreases towards the side downstream of the bottom current,accompanied by an increasing mud content.

Key words: bottom current, gravity flow, interplay, lobe, Rovuma Basin

中图分类号:

P512.32

刘钰星, 陈宇航, 范国章, 李林, 鲁银涛, 左国平, 曹全斌, 丁群峰. 底流与重力流交互作用下的朵体沉积特征: 以东非鲁伍马盆地中新统为例^*[J]. 古地理学报, 2024, 26(4): 1005-1016.

LIU Yuxing, CHEN Yuhang, FAN Guozhang, LI Lin, LU Yintao, ZUO Guoping, CAO Quanbin, DING Qunfeng. Sedimentary characteristics of lobes formed by interacting bottom currents and gravity flows: a case study from the Miocene in Rovuma Basin,East Africa[J]. JOPC, 2024, 26(4): 1005-1016.

http://www.gdlxb.cn/CN/Y2024/V26/I4/1005

参考文献

[1] 陈宇航,姚根顺,吕福亮,邵大力,鲁银涛,孙辉. 2020. 东非陆缘深水沉积演化及控制因素: 以鲁伍马盆地为例. 北京: 地质出版社,108-115.
[Chen Y H,Yao G S,Lü F L,Shao D L,Lu Y T,Sun H.2020. Evolution and Controlling Factors of Deep-water Sediments in the Continental Margin of East African: A Case Study of Rovuma Basin. Beijing: Geological Publishing House,108-115]
[2] 陈宇航,姚根顺,邵大力,鲁银涛,吕福亮,曹全斌,唐鹏程,李仕芳. 2021. 坦桑尼亚滨海盆地陆坡峡谷沉积特征及其控制因素. 古地理学报, 23(6): 1158-1173.
[Chen Y H,Yao G S,Shao D L,Lu Y T,Lü F L,Cao Q B,Tang P C,Li S F.2021. Sedimentary characteristics and its controlling factors of continental slope canyons in Tanzania Coastal Basin. Journal of Palaeogeography(Chinese Edition), 23(6): 1158-1173]
[3] 龚承林,王英民. 2023. 深海重力流与底流交互作用. 北京: 科学出版社,1-5.
[Gong C L,Wang Y M.2023. Interaction between Deep-sea Gravity Flow and Bottom Current. Beijing: Science Press,1-5]
[4] 何幼斌,罗顺社,高振中. 2004. 内波、内潮汐沉积研究现状与进展. 江汉石油学院学报, 26(1): 5-10,141.
[He Y B,Luo S S,Gao Z Z.2004. Current situation and advance of internal wave and internal tide deposit study. Journal of Jianghan Petroleum Institute, 26(1): 5-10,141]
[5] 李冬,王英民,王永凤,徐强,王杰平. 2011. 琼东南盆地中央峡谷深水天然堤—溢岸沉积. 沉积学报, 29(4): 689-694.
[Li D,Wang Y M,Wang Y F,Xu Q,Wang J P.2011 The sedimentary and foreground of prospect for levee-overbank in central canyon,Qiongdongnan Basin. Acta Sedimentologica Sinica, 29(4): 689-694]
[6] 李华,王英民,徐强,卓海腾,吴嘉鹏,唐武,李冬,徐艳霞. 2014. 南海北部珠江口盆地重力流与等深流交互作用沉积特征、过程及沉积模式. 地质学报, 88(6): 1120-1129.
[Li H,Wang Y M,Xu Q,Zhuo H T,Wu J P,Tang W,Li D,Xu Y X.2014. Interactions between down-slope and along-slope processes on the northern slope of South China Sea: products,processes,and depositional model. Acta Geologica Sinica, 88(6): 1120-1129]
[7] 史卜庆,丁梁波,马宏霞,孙辉,张颖,许小勇,王红平,范国章. 2023. 东非海域大型深水沉积体系及油气成藏特征. 岩性油气藏, 35(6): 10-17.
[Shi B Q,Ding L B,Ma H X,Sun H,Zhang Y,Xu X Y,Wang H P,Fan G Z.2023. Characteristics of hydrocarbon accumulation in deep-water depositional system in offshore East Africa. Lithologic Reservoirs, 35(6): 10-17]
[8] 孙辉,吕福亮,范国章,刘少治,鲁银涛,陈宇航. 2017. 三级层序内受底流影响的富砂深水沉积演化规律: 以东非鲁武马盆地中中新统为例. 天然气地球科学, 28(1): 106-115.
[Sun H,Lü F L,Fan G Z,Liu S Z,Lu Y T,Chen Y H.2017. Evolution of deepwater sand-rich sediments affected by bottom currents in the 3^rd order sequences: a case study of Middle Miocene in the Ruvuma Basin. Natural Gas Geoscience, 28(1): 106-115]
[9] 王玉柱,王海荣,高红芳,王志宏,郑良合,吕友生. 2010. 等深流作用机制和沉积的研究进展. 古地理学报, 12(2): 141-150.
[Wang Y Z,Wang H R,Gao H F,Wang Z H,Zheng L H,Lü Y S.2010. Contour current dynamics process and deposits: a review. Journal of Palaeogeography(Chinese Edition), 12(2): 141-150]
[10] 吴嘉鹏,王英民,王海荣,李华,彭学超,邱燕,李冬. 2012. 深水重力流与底流交互作用研究进展. 地质论评, 58(6): 1110-1120.
[Wu J P,Wang Y M,Wang H R,Li H,Peng X C,Qiu Y,Li D.2012. The interaction between deep-water turbidity and bottom currents: a review. Geological Review, 58(6): 1110-1120]
[11] 张光亚,刘小兵,温志新,王兆明,宋成鹏. 2015. 东非被动大陆边缘盆地构造: 沉积特征及其对大气田富集的控制作用. 中国石油勘探, 20(4): 71-80.
[Zhang G Y,Liu X B,Wen Z X,Wang Z M,Song C P.2015. Structural and sedimentary characteristics of passive continental margin basins in East Africa and their effect on the formation of giant gas fields. China Petroleum Exploration, 20(4): 71-80]
[12] 张兴阳,高振中,姚雪根. 1999. 北大西洋洛克尔海槽东北部内波沉积: 深水大型沉积物波成因的再解释. 沉积学报, 17(3): 464-472.
[Zhang X Y,Gao Z Z,Yao X G.1999. Internal-wave deposits in the north-eastern Rockall Trough,North Atlantic Ocean: reinterpretation of deep-water sediment waves formation. Acta Sedimentologica Sinica, 17(3): 464-472]
[13] Beaubouef R T.2004. Deep-water leveed-channel complexes of the Cerro Toro Formation,Upper Cretaceous,southern Chile. AAPG Bulletin, 88(11): 1471-1500.
[14] Bowen A J,Normark W R,Piper D J W.1984. Modelling of turbidity currents on navy submarine fan,California continental borderland. Sedimentology, 31(2): 169-185.
[15] Brackenridge R E,Hernández-Molina F J,Stow D A V,Llave E.2013. A Pliocene mixed contourite-turbidite system offshore the Algarve Margin,Gulf of Cadiz: seismic response,margin evolution and reservoir implications. Marine and Petroleum Geology, 46: 36-50.
[16] Breitzke M,Wiles E,Krocker R,Watkeys M K,Jokat W.2017. Seafloor morphology in the Mozambique Channel: evidence for long-term persistent bottom-current flow and deep-reaching eddy activity. Marine Geophysical Research, 38: 241-269.
[17] Chen Y H,Yao G S,Wang X F,Lü F L,Shao D L,Lu Y T,Cao Q B,Tang P C.2020. Flow processes of the interaction between turbidity flows and bottom currents in sinuous unidirectionally migrating channels: an example from the Oligocene channels in the Rovuma Basin,offshore Mozambique. Sedimentary Geology, 404: 105680.
[18] de Ruijter W P M,Ridderinkhof H,Lutjeharms J R E,Schouten M W,Veth C.2002. Observations of the flow in the Mozambique Channel. Geophysical Research Letters, 29(10): 1502.
[19] Fonnesu M,Palermo D,Galbiati M,Marchesini M,Bonamini E,Bendias D2020. A new world-class deep-water play-type,deposited by the syndepositional interaction of turbidity flows and bottom currents: the giant Eocene Coral Field in northern Mozambique. Marine and Petroleum Geology, 111: 179-201.
[20] Fuhrmann A,Kane I A,Clare M A,Ferguson R A,Schomacker E,Bonamini E,Contreras F A.2020. Hybrid turbidite-drift channel complexes: an integrated multiscale model. Geology, 48(6): 562-568.
[21] Gervais A,Savoye B,Mulder T,Gonthier E.2006. Sandy modern turbidite lobes: a new insight from high resolution seismic data. Marine and Petroleum Geology, 23(4): 485-502.
[22] Gong C L,Wang Y M,Steel R J,Peakall J,Zhao X M,Sun Q L.2016. Flow processes and sedimentation in unidirectionally migrating deep-water channels: from a three-dimensional seismic perspective. Sedimentology, 63(3): 645-661.
[23] Gong C L,Wang Y M,Rebesco M,Salon S,Steel R J.2018. How do turbidity flows interact with contour currents in unidirectionally migrating deep-water channels?Geology, 46(6): 551-554.
[24] Hernández-Molina F J,Llave E,Stow D A V,García M,Somoza L,Vázquez J T,Lobo F J,Maestro A,Díaz del Río V,León R,Medialdea T,Gardner J.2006. The contourite depositional system of the Gulf of Cádiz: a sedimentary model related to the bottom current activity of the Mediterranean outflow water and its interaction with the continental margin. Deep Sea Research Part Ⅱ: Topical Studies in Oceanography, 53: 1420-1463.
[25] Hernández-Molina F J,Paterlini M,Violante R,Marshall P,de Isasi M,Somoza L,Rebesco M.2009. Contourite depositional system on the Argentine Slope: an exceptional record of the influence of Antarctic water masses. Geology, 37(6): 507-510.
[26] Kenyon N H.1986. Evidence from bedforms for a strong poleward current along the upper continental slope of northwest Europe. Marine Geology, 72(1-2): 187-198.
[27] Kolla V,Posamentier H W,Wood L J.2007. Deep-water and fluvial sinuous channels: characteristics,similarities and dissimilarities,and modes of formation. Marine and Petroleum Geology, 24(6-9): 388-405.
[28] Macgregor D.2018. History of the development of Permian-Cretaceous rifts in East Africa: a series of interpreted maps through time. Petroleum Geoscience, 24: 8-20.
[29] Rebesco M,Stow D.2001. Seismic expression of contourites and related deposits: a preface. Marine Geophysical Researches, 22: 303-308.
[30] Rebesco M,Hernández-Molina F J,Van Rooij D,WaHlin A.2014. Contourites and associated sediments controlled by deep-water circulation processes: state-of-the-art and future considerations. Marine Geology, 352: 111-154.
[31] Schlüter P,Uenzelmann-Neben G.2007. Seismostratigraphic analysis of the Transkei Basin: a history of deep sea current controlled sedimentation. Marine Geology, 240(1-4): 99-111.
[32] Sequeiros O E.2012. Estimating turbidity current conditions from channel morphology: a Froude number approach. Journal of Geophysical Research: Oceans,117(C4): C04003.
[33] Shanmugam G.2008. Chapter 5 deep-water bottom currents and their deposits. In: Rebesco M,Camerlenghi A(eds). Developments in Sedimentology. Amsterdam: Elsevier Science,59-81.
[34] Shanmugam G.2014. Modern internal waves and internal tides along oceanic pycnoclines: challenges and implications for ancient deep-marine baroclinic sands: reply. AAPG Bulletin, 98(4): 858-879.
[35] Stow D A V,Hernández-Molina F J,Llave E,Bruno M,García M,Díaz del Rio V,Somoza L,Brackenridge R E.2013. The Cadiz Contourite Channel: sandy contourites,bedforms and dynamic current interaction. Marine Geology, 343: 99-114.
[36] van Aken H M,Ridderinkhof H,de Ruijter W P M. 2004. North Atlantic deep water in the south-western Indian Ocean. Deep Sea Research Part I: Oceanographic Research Papers, 51(6): 755-776.
[37] Viana A R.2008. Chapter 23 economic relevance of contourites. In: Rebesco M,Camerlenghi A(eds). Developments in Sedimentology. Amsterdam: Elsevier Science,493-510.

选择文件类型/文献管理软件名称

选择包含的内容

底流与重力流交互作用下的朵体沉积特征: 以东非鲁伍马盆地中新统为例^*

Sedimentary characteristics of lobes formed by interacting bottom currents and gravity flows: a case study from the Miocene in Rovuma Basin,East Africa

RichHTML

PDF

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	李攀, 肖冬生, 师效飞, 马强, 林潼, 杨润泽. 巨型事件层综述^*[J]. 古地理学报, 2024, 26(5): 1271-1286.
[2]	冯有良, 邹才能, 杨智, 蒋文琦, 张天舒, 张洪, 刘畅, 王小妮. 中国断陷和坳陷湖盆高可容纳空间层序细粒重力流沉积及其页岩油意义^*[J]. 古地理学报, 2024, 26(4): 941-961.
[3]	王小妮, 杨智, 冯有良, 蒋文琦, 龙国徽, 伍坤宇, 张洪, 侯鸣秋, 邢浩婷, 张天舒, 刘畅, 魏琪钊. 咸水湖泊细粒重力流沉积及油气意义: 以柴达木盆地英西地区下干柴沟组上段为例^*[J]. 古地理学报, 2024, 26(4): 985-1004.
[4]	于吉星, 杨田, 田景春, 蔡来星, 任启强, 郭为雪. 深水重力流沉积油气勘探中的几个基础沉积学问题与研究展望^*[J]. 古地理学报, 2023, 25(6): 1299-1314.
[5]	孙浩南, 谈明轩, 付亦霖, 崔浩楠, 陈绵培. 西秦岭卓尼地区晚三叠世细粒重力流沉积过程及成因机制研究^*[J]. 古地理学报, 2023, 25(6): 1315-1329.
[6]	张自力, 李琦, 朱筱敏, 谈明轩, 张锐锋, 曹兰柱, 李凤勋, 单帅强. 陆相断陷湖盆重力流湖底扇沉积与地震响应特征分析: 以渤海湾盆地霸县凹陷古近系沙河街组为例^*[J]. 古地理学报, 2023, 25(5): 1049-1068.
[7]	吕奇奇, 辛红刚, 王林, 罗顺社, 淡卫东, 冯胜斌. 鄂尔多斯盆地宁县地区三叠系延长组7段湖盆细粒重力流沉积类型、特征及模式^*[J]. 古地理学报, 2023, 25(4): 823-840.
[8]	梁积伟, 宗浩, 冯昆明, 常小斌, 李汉林, 冯振伟, 郑萌, 陈欣, 李文厚. 鄂尔多斯盆地奥陶系平凉组深水沉积特征^*[J]. 古地理学报, 2023, 25(3): 554-572.
[9]	谈梦婷, 李华, 何幼斌, 葛稳稳, 孙玉玺, 冯斌, 于星. 鄂尔多斯盆地西缘奥陶系拉什仲组复合水道沉积特征及演化^*[J]. 古地理学报, 2023, 25(1): 119-132.
[10]	张佳佳, 吴胜和, 王瑞峰, 王敏, 陈梅, 王晓丰, 徐庆岩, 熊绮聪, 余季陶, 王黎. 东非鲁伍马盆地深水X气藏海底扇储层构型研究:重力流—底流交互作用的指示意义^*[J]. 古地理学报, 2023, 25(1): 163-179.
[11]	单新, 李顺利, 石学法, 谭程鹏. 海峡沉积研究进展^*[J]. 古地理学报, 2022, 24(6): 1058-1072.
[12]	周伟. 深水单向迁移水道建造模式与成因机制研究进展^*[J]. 古地理学报, 2021, 23(6): 1082-1093.
[13]	刘飞, 赵晓明, 冯潇飞, 葛家旺, 杨莉, 杨宝泉, 杨希濮. 基于重力流相的深水水道分类方案研究^*[J]. 古地理学报, 2021, 23(5): 951-966.
[14]	田荣恒, 鲜本忠, 晁储志, 刘建平, 张国栋, 王俊辉, 陈鹏. 湖相重力流水道沉积特征与沉积模式:以鄂尔多斯盆地瑶曲铁路桥剖面三叠系延长组为例^*[J]. 古地理学报, 2021, 23(5): 967-982.
[15]	邢作昌, 张忠涛, 林畅松, 张博, 洪方浩, 宫越. 珠江口盆地荔湾凹陷晚渐新世—早中新世重力流沉积类型及其特征[J]. 古地理学报, 2020, 22(6): 1143-1156.

模态框（Modal）标题

选择文件类型/文献管理软件名称

选择包含的内容

底流与重力流交互作用下的朵体沉积特征: 以东非鲁伍马盆地中新统为例*

Sedimentary characteristics of lobes formed by interacting bottom currents and gravity flows: a case study from the Miocene in Rovuma Basin,East Africa

RichHTML

PDF

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

底流与重力流交互作用下的朵体沉积特征: 以东非鲁伍马盆地中新统为例^*