坦桑尼亚盆地渐新统深水重力流沉积特征及控制因素<sup>*</sup>

doi:10.7605/gdlxb.2019.06.066

Abstract
Figure/Table
References()
Related Citation (15)
Read Tracking
Download Tracking

Download: PDF (8575 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS) Supporting Info

Abstract In recent years, several large-scale gas reservoirs have been discovered in Tanzania Basin of the East Africa. However, the study of sedimentary characteristics, formation mechanism and main controlling factors are relatively weak. Based on drilling, logging and 2D seismic data, with the comprehensive analysis of the sedimentary characteristics, it is found that deep-water gravity-flow deposits were developed in Oligocene of Tanzania Basin. The deep-water deposits could be divided into 3 types: channels, levees and lobes, among which channels and lobes are dominated. Moreover, deep-water channels could be further divided into the complex channel, the lateral-migrational channel, the vertical-aggradational channel and the isolated channel, according to the occurrence location, external morphology, internal architecture and sedimentary style. There were variations in sedimentary characteristics of Oligocene gravity-flow deposits from south to north of the Tanzania Basin. In the south of the basin, the small-scale isolated channels and lobe deposits were developed, which have a SW-NE orientation. In the middle of the basin,complex channels, vertical-aggradational channels, lateral-migrational channels and lobe deposits were mainly developed, with a overall orientation of NW-SE direction. In the north of the basin, lateral-migrational channels, levees and lobe deposits were dominated, which have similar orientations to those of the middle part. Taking the variations among the south, the middle and the north parts of Tanzania Basin and the coupling relationships of Source-to-Sink into consideration, the elements of Source-to-Sink system is comparatively analyzed. Research suggests that the development and distribution of deep-water gravity-flow deposits in the study area are mainly affected by tectonic movements (the tectonic uplift, mid-ocean ridge spreading, and fault activity), source systems and the shelf-slope topography.

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	Guo Xiao
	Li Hua
	Liang Jian-She
	Qiu Chun-Guang
	Xie Dong-Ning
	Feng Xin
	Rao Su
	He You-Bin

Key words： Tanzania Basin Oligocene gravity-flow deposits controlling factors sedimentary model

Received: 06 June 2019

ZTFLH:

TE121.3

Fund:Financially supported by the National Science and Technology Major Project of China(No.2017ZX05032-002-003)

Corresponding Authors: He You-Bin,born in 1964,is a professor and Ph.D. supervisor in school of Geosciences,Yangtze University. He is currently engaged in the research on sedimentology.E-mail: 100709@yangtzeu.edu.cn.

About author: Guo Xiao,born in 1993,is a master candidate in school of Geosciences,Yangtze University,and is currently engaged in the research on sedimentology. E-mail: guoxiao199410@126.com.

Cite this article:

Guo Xiao,Li Hua,Liang Jian-She et al. Sedimentary characteristics and controlling factors of deep-water gravity flow deposits of the Oligocene in Tanzania Basin[J]. JOPC, 2019, 21(6): 971-982.

URL:

http://journal09.magtechjournal.com/gdlxb/EN/10.7605/gdlxb.2019.06.066 OR http://journal09.magtechjournal.com/gdlxb/EN/Y2019/V21/I6/971

[1] 崔志骅. 2016. 东非海岸重点盆地油气地质特征及勘探潜力分析. 浙江大学硕士学位论文.
[Cui Z H.2016. Evaluation on characteristics of petroleum geology and exploration potential of coastal key basins in East Africa. Masteral Dissertation of Zhejiang University]
[2] 金宠,陈安清,楼章华,金爱民,朱蓉,陶丽,徐胜林. 2012. 东非构造演化与油气成藏规律初探. 吉林大学学报: 地球科学版,42(增刊2): 121-130.
[Jin C,Chen A Q,Lou Z H,Jin A M,Zhu R,Tao L,Xu S L.2012. Tectonic evolution and hydrocarbon accumulation principle in East Africa. Journal of Jilin University: Earth Science Edition,42(supplement 2): 121-130]
[3] 何云龙,解习农,李俊良,张成,苏明. 2010. 琼东南盆地陆坡体系发育特征及其控制因素. 地质科技情报, 29(2): 118-122.
[He Y L,Xie X N,Li J L,Zhang C,Su M.2010. Depositional characteristics and controlling factors of continental slope system in the Qiongdongnan Basin. Geological Science and Technology Information, 29(2): 118-122]
[4] 李华,何幼斌,王振奇. 2011. 深水高弯度水道—堤岸沉积体系形态及特征. 古地理学报, 13(2): 139-149.
[Li H,He Y B,Wang Z Q.2011. Morphology and characteristics of deep waterhigh sinuous channel-levee system. Journal of Palaeogeography(Chinese Edition), 13(2): 139-149]
[5] 李华,王英民,徐强,韩自亮,徐艳霞. 2013. 深水单向迁移水道—堤岸沉积体系特征及形成过程. 现代地质, 27(3): 653-661.
[Li H,Wang Y M,Xu Q,Han Z L,Xu Y X.2013. Characteristics and processes of deep water unidirectionally-migrating channel-levee system. Geoscience, 27(3): 653-661]
[6] 李华,何幼斌,冯斌,郝烃,苏帅亦,张灿,王季欣. 2018. 鄂尔多斯盆地西缘奥陶系拉什仲组深水水道沉积类型及演化. 地球科学, 43(6): 2149-2159.
[Li H,He Y B,Feng B,Hao T,Su S Y,Zhang C,Wang J X.2018. Type and evolution of deep-water channel deposits of Ordovician Lashizhong Formation in western margin of Ordos Basin. Earth Science, 43(6): 2149-2159]
[7] 李磊,王英民,徐强,黄志超. 2012. 被动陆缘深水重力流沉积单元及沉积体系: 以尼日尔三角洲和珠江口盆地白云凹陷深水区为例. 地质论评, 58(5): 846-853.
[Li L,Wang Y M,Xu Q,Huang Z C.2012. Deep-water gravity flow depositional elements and depositional systems in passive margin: Case studies in deep-water areas of Niger Delta and Baiyun Sag,Pearl River Mouth Basin. Geological Review, 58(5): 846-853]
[8] 廖计华,徐强,陈莹,王颖,蔡露露,邹梦君,曾清波,焦振华. 2016. 白云—荔湾凹陷珠江组大型深水水道体系沉积特征及成因机制. 地球科学, 41(6): 1041-1054.
[Liao J H,Xu Q,Chen Y,Wang Y,Cai L L,Zou M J,Zeng Q B,Jiao Z H.2016. Sedimentary characteristics and genesis of deepwater channel system in Zhujiang Formation of Baiyun-Liwan Sag. Earth Science, 41(6): 1041-1054]
[9] 骆帅兵,张莉,雷振宇,王晓兵,杨雨晨. 2017. 陆坡盆地体系深水重力流形成机制、沉积模式及应用实例探讨. 石油实验地质, 39(6): 747-754.
[Luo S B,Zhang L,Lei Z Y,Wang X B,Yang Y C.2017. Formation mechanism,sedimentary model and typical exampleof a deep-water gravity flow in continental slope-basin systems. Petroleum Geology & Experiment, 39(6): 747-754]
[10] 苏明,张成,解习农,王振峰,姜涛,何云龙,张翠梅. 2014. 深水峡谷体系控制因素分析: 以南海北部琼东南盆地中央峡谷体系为例. 中国科学(D辑): 地球科学, 44(8): 1807-1820.
[Su M,Zhang C,Xie X N,Wang Z F,Jiang T,He Y L,Zhang C M.2014. Controlling factors on the submarine canyon system: A case study of the Central Canyon System in the Qiongdongnan Basin,northern South China Sea. Science China(Seri.D): Earth Sciences, 44(8): 1807-1820]
[11] 孙立春,汪洪强,何娟,王龙,郭丽娜,倪军娥. 2014. 尼日利亚海上区块近海底深水水道体系地震响应特征与沉积模式. 沉积学报, 32(6): 1140-1152.
[Sun L C,Wang H Q,He J,Wang L,Guo L N,Ni J E.2014. Seismic characteristics and depositional model of near-seabed submarine leveed-channel complexes in Nigeria Offshore Block,West Africa. Acta Sedimentologica Sinica, 32(6): 1140-1152]
[12] 孙玉梅,孙涛,许志刚. 2016. 东非海岸坦桑尼亚盆地烃源岩特征与油气来源. 中国海上油气, 28(1): 13-19.
[Sun Y M,Sun T,Xu Z G.2016. Source rock characteristics and oil-gas origins in Tanzania basin,East Africa coast. China Offshore Oil and Gas, 28(1): 13-19]
[13] 王颖,王晓州,王英民,辛仁臣,赵志魁. 2009. 大型坳陷湖盆坡折带背景下的重力流沉积模式. 沉积学报, 27(6): 1076-1083.
[Wang Y,Wang X Z,Wang Y M,Xin R C,Zhao Z K.2009. Depositional model gravity flow of slope in large down warped lake basins. Acta Sedimentologica Sinica, 27(6): 1076-1083]
[14] 温志新,王兆明,宋成鹏,贺正军,刘小兵. 2015. 东非被动大陆边缘盆地结构构造差异与油气勘探. 石油勘探与开发, 42(5): 671-680.
[Wen Z X,Wang Z M,Song C P,He Z J,Liu X B.2015. Structural architecture difference and petroleum exploration of passive continental margin basins in east Africa. Petroleum Exploration and Development, 42(5): 671-680]
[15] 张功成,屈红军,张凤廉,陈硕,杨海长,赵钊,赵冲. 2019. 全球深水油气重大新发现及启示. 石油学报,40(1): 1-34,55.
[Zhang G C, Qu H J, Zhang F L, Chen S, Yang H C, Zhao C.2019. Major new discoveries of oil and gas in global deepwaters and enlightenment. Acta Petrolei Sinica, 40(1): 1-34,55]
[16] 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]
[17] 赵家斌,钟广法. 2018. 构造活动对海底峡谷地貌形态的影响. 海洋地质前沿, 34(12): 1-13.
[Zhao J B,Zhong G F.2018. A review on geomorphic response of submarine canyons to tectonic deformation. Marine Geology Frontiers, 34(12): 1-13]
[18] 朱红涛,徐长贵,朱筱敏,曾洪流,姜在兴,刘可禹. 2017. 陆相盆地源-汇系统要素耦合研究进展. 地球科学, 42(11): 1851-1870.
[Zhu H T,Xu C G,Zhu X M,Zeng H L,Jiang Z X,Liu K Y.2017. Advances of the source-to-sink units and coupling model research in continental bsain. Earth Science, 42(11): 1851-1870]
[19] 朱秀,朱红涛,曾洪流,杨香华. 2017. 云南洱海现代湖盆源-汇系统划分、特征及差异. 地球科学, 42(11): 2010-2024.
[Zhu X,Zhu H T,Zeng H L,Yang X H.2017. Subdivision,characteristics,and varieties of the Source-to-Sink systems of the modern lake Erhai Basin,Yunnan Province. Earth Science, 42(11): 2010-2024]
[20] Bosellini A.1986. East Africa continental margins. Geology, 14(1): 76-78.
[21] Cope M J.2000. Tanzania’s Mafia deepwater basin indicates potential on new seismic data. Oil and Gas Journal, 98: 40-49.
[22] Mcdonough K J,Bouanga E,Pierard C,Horn B,Emmet P,Gross J,Danforth A,Sterne N,Granath J.2013. Wheeler transformed 2D seismic data yield fan chronostratigraphy of offshore Tanzania. The Leading Edge, 32(2): 162-170.
[23] Said A,Moder C,Clark S,Abdelmalak M M.2015. Sedimentary budgets of the Tanzania coastal basin and implications for uplift history of the East African rift system. Journal of African Earth Science, 111: 288-295.
[24] Tanzania Petroleum DevelopmentCorporation(TPDC). 2015. Summary of Deep Well in Tanzania[EB/OL]. http: www.tpdc-tz.com/deepwells.php,2.