深层—超深层高孔高渗碎屑岩油气藏地质特征、形成条件及成藏模式——以墨西哥湾盆地为例

doi:10.7623/syxb202104004

石油学报 ›› 2021, Vol. 42 ›› Issue (4): 466-480.DOI: 10.7623/syxb202104004

深层—超深层高孔高渗碎屑岩油气藏地质特征、形成条件及成藏模式——以墨西哥湾盆地为例

张兴文^1,2, 庞雄奇^1,2, 李才俊^1,2, 于吉旺^1,2, 汪文洋^1,2, 肖惠译², 李昌荣^1,2, 余季陶²

1. 中国石油大学(北京)油气资源与探测国家重点实验室北京 102249;
2. 中国石油大学(北京)地球科学学院北京 102249

收稿日期:2020-01-14 修回日期:2021-03-31 出版日期:2021-04-25 发布日期:2021-05-11
通讯作者: 庞雄奇,男,1961年8月生,1982年获江汉石油学院学士学位,1991年获中国地质大学博士学位,现为中国石油大学(北京)教授、博士生导师,主要从事油气藏形成与分布预测方向的教学和科研工作。Email:pangxq@cup.edu.cn
作者简介:张兴文,男,1997年7月生,2018年获西安石油大学学士学位,现为中国石油大学(北京)地质资源与地质工程专业硕士研究生,主要从事油气藏形成与分布预测研究工作。Email:zxw_geology@163.com
基金资助:
国家重点基础研究发展计划（973）项目（2011CB201100）资助。

Geological characteristics, formation conditions and accumulation model of deep and ultra-deep,high-porosity and high-permeability clastic reservoirs: a case study of Gulf of Mexico Basin

Zhang Xingwen^1,2, Pang Xiongqi^1,2, Li Caijun^1,2, Yu Jiwang^1,2, Wang Wenyang^1,2, Xiao Huiyi², Li Changrong^1,2, Yu Jitao²

1. State Key Laboratory of Petroleum Resources and Prospecting, China University of Petroleum, Beijing 102249, China;
2. College of Geosciences, China University of Petroleum, Beijing 102249, China

Received:2020-01-14 Revised:2021-03-31 Online:2021-04-25 Published:2021-05-11

摘要/Abstract

摘要： 深层与超深层作为当前墨西哥湾盆地油气勘探的热点领域，具有巨大的油气资源潜力，分析深层—超深层油气藏的地质特征、形成条件及其成藏模式对于明确深层—超深层油气藏的分布规律具有重要意义。与中层—浅层相比，墨西哥湾盆地深层—超深层具有较低的地温梯度和较高的压力梯度，发育大量高孔高渗碎屑岩油气藏。不均衡压实成因型超压是深部高孔高渗碎屑岩储层形成和油气富集的主要原因，其与浮力共同构成深部油气运移的主要动力。盆地北部和南部的沿海平原、陆架和陆坡发育区域性厚层状盐岩层。盐岩变形诱导邻近地层发育一系列断层、形成多种构造圈闭，为深层—超深层油气提供了极好的运移通道和聚集场所。墨西哥湾盆地深层—超深层高孔高渗碎屑岩油气成藏与不均衡压实型超压和区域性厚层状盐岩发育密切相关，表现为"高压驱动、高孔高渗聚集、高点赋存和高位封盖"的成藏模式。被动大陆边缘盆地盐下探区是深层—超深层高孔高渗碎屑岩油气藏的有利发育区和勘探热点区。

关键词: 深层—超深层, 高孔高渗碎屑岩油气藏, 地质特征, 形成条件, 成藏模式, 墨西哥湾盆地

Abstract: As the hotspots for oil and gas exploration in the Gulf of Mexico, deep and ultra-deep formations have huge oil and gas resource potential. To analyze the geological characteristics, formation conditions and accumulation mode of deep-ultra-deep oil and gas reservoirs is crucial for clarifying the distribution law of deep -ultra-deep oil and gas reservoirs. Compared with the middle-shallow formations, the deep-ultra-deep formations in the Gulf of Mexico Basin have lower geothermal gradients and higher pressure gradients, with the development of plenty of high-porosity and high-permeability clastic reservoirs. Overpressure due to disequilibrium compaction is the main reason for the formation of deep high-porosity and high-permeability clastic reservoirs as well as oil and gas accumulation. Together with buoyancy, they constitute the main driving force for deep oil and gas migration. Thick-layered salt rock is developed in regional areas of the coastal plains, continental shelf and continental slope in the north and south of the basin. Salt rock deformation induces the development of a series of faults in adjacent strata and forms a variety of structural traps, providing excellent migration pathways and accumulation sites for deep and ultra-deep oil and gas. The hydrocarbon accumulation in the deep-ultra-deep, high-porosity and high-permeability clastic rock in the Gulf of Mexico Basin is closely related to the overpressure due to disequilibrium compaction and the development of regional thick-layered salt rock, showing the accumulation model of "hydrocarbons driven by high pressures, accumulating in high-porosity and high-permeability reservoirs, storing at high point of traps and sealed by overlying cap rocks". Deep-ultra-deep, high-porosity and high-permeability clastic oil and gas reservoirs are prone to be developed in pre-salt layers of the passive continental margin basins, which can become the hot spots for the exploration of deep-ultra-deep, high-porosity and high-permeability clastic reservoirs.

Key words: deep and ultra-deep formation, high-porosity and high-permeability clastic reservoirs, geological characteristics, formation conditions, accumulation model, Gulf of Mexico Basin

中图分类号:

TE122.1

张兴文, 庞雄奇, 李才俊, 于吉旺, 汪文洋, 肖惠译, 李昌荣, 余季陶. 深层—超深层高孔高渗碎屑岩油气藏地质特征、形成条件及成藏模式——以墨西哥湾盆地为例[J]. 石油学报, 2021, 42(4): 466-480.

Zhang Xingwen, Pang Xiongqi, Li Caijun, Yu Jiwang, Wang Wenyang, Xiao Huiyi, Li Changrong, Yu Jitao. Geological characteristics, formation conditions and accumulation model of deep and ultra-deep,high-porosity and high-permeability clastic reservoirs: a case study of Gulf of Mexico Basin[J]. Acta Petrolei Sinica, 2021, 42(4): 466-480.

参考文献

[1] 朱光有,张水昌.中国深层油气成藏条件与勘探潜力[J].石油学报,2009,30(6):793-802.
ZHU Guangyou,ZHANG Shuichang.Hydrocarbon accumulation conditions and exploration potential of deep reservoirs in China[J].Acta Petrolei Sinica,2009,30(6):793-802.
[2] 马永生,何治亮,赵培荣,等.深层-超深层碳酸盐岩储层形成机理新进展[J].石油学报,2019,40(12):1415-1425.
MA Yongsheng,HE Zhiliang,ZHAO Peirong,et al.A new progress in Formation mechanism of deep and ultra-deep carbonate reservoir[J].Acta Petrolei Sinica,2019,40(12):1415-1425.
[3] 孙龙德,邹才能,朱如凯,等.中国深层油气形成、分布与潜力分析[J].石油勘探与开发,2013,40(6):641-649.
SUN Longde,ZOU Caineng,ZHU Rukai,et al.Formation,distribution and potential of deep hydrocarbon resources in China[J].Petroleum Exploration and Development,2013,40(6):641-649.
[4] 白国平,曹斌风.全球深层油气藏及其分布规律[J].石油与天然气地质,2014,35(1):19-25.
BAI Guoping,CAO Binfeng.Characteristics and distribution patterns of deep petroleum accumulations in the world[J].Oil & Gas Geology,2014,35(1):19-25.
[5] 易士威,李明鹏,郭绪杰,等.塔里木盆地寒武系盐下勘探领域的重大突破方向[J].石油学报,2019,40(11):1281-1295.
YI Shiwei,LI Mingpeng,GUO Xujie,et al.Breakthrough direction of Cambrian pre-salt exploration fields in Tarim Basin[J].Acta Petrolei Sinica,2019,40(11):1281-1295.
[6] 庞雄奇,汪文洋,汪英勋,等.含油气盆地深层与中浅层油气成藏条件和特征差异性比较[J].石油学报,2015,36(10):1167-1187.
PANG Xiongqi,WANG Wenyang,WANG Yingxun,et al.Comparison of otherness on hydrocarbon accumulation conditions and characteristics between deep and middle-shallow in petroliferous basins[J].Acta Petrolei Sinica,2015,36(10):1167-1187.
[7] 贾承造,庞雄奇.深层油气地质理论研究进展与主要发展方向[J].石油学报,2015,36(12):1457-1469.
JIA Chengzao,PANG Xiongqi.Research processes and main development directions of deep hydrocarbon geological theories[J].Acta Petrolei Sinica,2015,36(12):1457-1469.
[8] 何治亮,金晓辉,沃玉进,等.中国海相超深层碳酸盐岩油气成藏特点及勘探领域[J].中国石油勘探,2016,21(1):3-14.
HE Zhiliang,JIN Xiaohui,WO Yujin,et al.Hydrocarbon accumulation characteristics and exploration domains of ultra-deep marine carbonates in China[J].China Petroleum Exploration,2016,21(1):3-14.
[9] 郭栋.坎波斯盆地盐下含油气系统分析与资源评价[D].北京:中国石油大学(北京),2016.
GUO Dong.Petroleum system analysis and exploration potential for the pre-salt sequences in the Campos Basin,Brazil[D].Beijing:China University of Petroleum,2016.
[10] 何登发,马永生,刘波,等.中国含油气盆地深层勘探的主要进展与科学问题[J].地学前缘,2019,26(1):1-12.
HE Dengfa,MA Yongsheng,LIU Bo,et al.Main advances and key issues for deep-seated exploration in petroliferous basins in China[J].Earth Science Frontiers,2019,26(1):1-12.
[11] ZHU Guangyou,ZHANG Zhiyao,ZHOU Xiaoxiao,et al.The complexity,secondary geochemical process,genetic mechanism and distribution prediction of deep marine oil and gas in the Tarim Basin,China[J].Earth-Science Reviews,2019,198:102930.
[12] 赵文智,汪泽成,张水昌,等.中国叠合盆地深层海相油气成藏条件与富集区带[J].科学通报,2007,52(S1):9-18.
ZHAO Wenzhi,WANG Zecheng,ZHANG Shuichang,et al.Analysis on forming conditions of deep marine reservoirs and their concentration belts in superimposed basins in China[J].Chinese Science Bulletin,2007,52(S1):12-27.
[13] 赵文智,胡素云,刘伟,等.再论中国陆上深层海相碳酸盐岩油气地质特征与勘探前景[J].天然气工业,2014,34(4):1-9.
ZHAO Wenzhi,HU Suyun,LIU Wei,et al.Petroleum geological features and exploration prospect in deep marine carbonate strata onshore China:a further discussion[J].Natural Gas Industry,2014,34(4):1-9.
[14] MA Yongsheng,GUO Tonglou,ZHAO Xuefeng,et al.The Formation mechanism of high-quality dolomite reservoir in the deep of Puguang Gas Field[J].Science in China series D:Earth Sciences,2008,51(S1):53-64.
[15] SUGISAKI R.Deep-seated gas emission induced by the earth tide:a basic observation for geochemical earthquake prediction[J].Science,1981,212(4500):1264-1266.
[16] 妥进才,王先彬,周世新,等.深层油气勘探现状与研究进展[J].天然气地球科学,1999,10(6):1-8.
TUO Jincai,WANG Xianbin,ZHOU Shixin,et al.Current situation about the research in oil and gas contained in deep formations and related progress[J].Natural Gas Geoscience,1999,10(6):1-8.
[17] 妥进才.深层油气研究现状及进展[J].地球科学进展,2002,17(4):565-571.
TUO Jincai.Research status and advances in deep oil and gas exploration[J].Advance in Earth Sciences,2002,17(4):565-571.
[18] М И 罗德任芙斯卡娅.深埋层的含油气性[J].天然气地球科学,2001,12(4/5):48-51.
RODRENVSKAYA М И.Hydrocarbon potential in deep layers[J].Natural Gas Geoscience,2001,12(4/5):48-51.
[19] П Г 迈哈蒂耶夫.深埋层含油气性的地温前提条件[J].天然气地球科学,2001,12(2):56-60.
MANHADIEPH П Г.Geothermal conditions of deep hydrocarbon-bearing layers[J].Natural Gas Geoscience, 2001,12(2):56-60.
[20] DYMAN T S,CROVELLI R A,BARTBERGER C E,et al.Worldwide estimates of deep natural gas resources based on the U.S.geological survey world petroleum assessment 2000[J].Natural Resources Research,2002,11(3):207-218.
[21] HAO Fang,ZOU Huayao,HUANG Baojia.Natural gas generation model and its response in accumulated fluids in the Yinggehai Basin[J].Science in China Series D:Earth Sciences,2003,46(11):1103-1112.
[22] PANG X Q,JIA C Z,WANG W Y.Petroleum geology features and research developments of hydrocarbon accumulation in deep petroliferous basins[J].Petroleum Science,2015,12(1):1-53.
[23] KAISER M J,NARRA S.A retrospective of oil and gas field development in the U.S.outer continental shelf gulf of Mexico,1947-2017[J]. Natural Resources Research,2019,28(3):685-715.
[24] 罗晓容,张立宽,付晓飞,等.深层油气成藏动力学研究进展[J].矿物岩石地球化学通报,2016,35(5):876-889.
LUO Xiaorong,ZHANG Likuan,FU Xiaofei,et al.Advances in dynamics of petroleum migration and accumulation in deep basins[J].Bulletin of Mineralogy,Petrology and Geochemistry,2016,35(5):876-889.
[25] KENNICUTT Ⅱ M C,MCDONALD T J,COMET P A,et al.The origins of petroleum in the Northern Gulf of Mexico[J].Geochimica et Cosmochimica Acta,1992,56(3):1259-1280.
[26] HOOD K C,WENGER L M,GROSS O P,et al.Hydrocarbon systems analysis of the northern Gulf of Mexico:delineation of hydrocarbon migration pathways using seeps and seismic imaging[M]//SCHUMACHER D,LESCHACK L A.Surface exploration case histories:applications of geochemistry,magnetics,and remote sensing.AAPG Bulletin,2002:25-40.
[27] WEIMER P,BOUROULLEC R,ADSON J,et al.An overview of the petroleum systems of the northern deep-water Gulf of Mexico[J].AAPG Bulletin,2017,101(7):941-993.
[28] COMET P A.Gulf of Mexico petroleum:a ring of black Gold[C]//AAPG Hedberg Conference,The evolution of petroleum systems analysis.Houston,Texas:AAPG,2019:1-21.
[29] MELLO U T,KARNER G D.Development of sediment overpressure and its effect on thermal maturation:application to the Gulf of Mexico Basin[J].AAPG Bulletin,1996,80(9):1367-1396.
[30] EHRENBERG S N,NADEAU P H,STEEN Ø.A megascale view of reservoir quality in producing sandstones from the offshore Gulf of Mexico[J].AAPG Bulletin,2008,92(2):145-164.
[31] 孙意博,王长城,施泽进.墨西哥湾盆地盐岩及盐构造对油气控制作用[J].长江大学学报:自科版,2015,12(20):12-16.
SUN Yibo,WANG Changcheng,SHI Zejin.The control of halite and salt structures on hydrocarbons in Gulf of Mexico Basin[J].Journal of Yangtze University:Natural Science Edition,2015,12(20):12-16.
[32] EWING T E,GALLOWAY W E.Evolution of the northern Gulf of Mexico sedimentary basin[M]//MIALL A D.The Sedimentary Basins of the United States and Canada.Amsterdam:Elsevier,2019:627-694.
[33] PILCHER R S,KILSDONK B,TRUDE J.Primary basins and their boundaries in the deep-water northern Gulf of Mexico:origin,trap types,and petroleum system implications[J].AAPG Bulletin,2011,95(2):219-240.
[34] NEHRING R.Oil and gas resources[M]//SALVADOR A.The Gulf of Mexico Basin.Boulder:Geological Society of America,1991:445-493.
[35] SNEDDEN J W,GALLOWAY W E.The Gulf of Mexico sedimentary basin:depositional evolution and petroleum applications[M].Cambridge:Cambridge University Press,2019:248-291.
[36] SALVADOR A.Late Triassic-Jurassic paleogeography and origin of Gulf of Mexico Basin[J].AAPG Bulletin,1987,71(4):419-451.
[37] GALLOWAY W E.Depositional evolution of the Gulf of Mexico sedimentary basin[J].Sedimentary Basins of the World,2008,5:505-549.
[38] MARTON G L,BUFFLER R T.Jurassic-early cretaceous tectono-paleogeographic evolution of the southeastern Gulf of Mexico Basin[J]. Sedimentary Basins of the World,1999,4:63-91.
[39] PINDELL J,Kennan L.Kinematic evolution of the Gulf of Mexico and Caribbean[M]//FILLON R H,ROSEN N C,WEIMER P,et al.Petroleum systems of deep-water basins-global and Gulf of Mexico experience.Houston:SEPM Society for Sedimentary Geology,2001:2-5.
[40] JACQUES J M,CLEGG H.Late Jurassic source rock distribution and quality in the Gulf of Mexico:inferences from plate tectonic modelling[J].GCAGS Transactions,2002,52:429-440.
[41] HARRY D L,LONDONO J.Structure and evolution of the central Gulf of Mexico continental margin and coastal plain,southeast United States[J].GSA Bulletin,2004,116(1/2):188-199.
[42] BIRD D E,BURKE K,HALL S A,et al.Gulf of Mexico tectonic history:hotspot tracks,crustal boundaries,and early salt distribution[J].AAPG Bulletin,2005,89(3):311-328.
[43] RUEDA-GAXIOLA J. The origin of the Gulf of Mexico Basin and its petroleum subbasins in Mexico,based on red bed and salt palynostratigraphy[M]//BARTOLINI C,BUFFLER R T,BLICKWEDE J.The Circum-Gulf of Mexico and the Caribbean:hydrocarbon habitats,basin formation,and plate tectonics:Tulsa,Oklahoma:AAPG,2003:246-282.
[44] WINKER C D,BUFFLER R T.Paleogeographic evolution of early deep-water Gulf of Mexico and margins,Jurassic to Middle Cretaceous (Comanchean)[J].AAPG Bulletin,1988,72(3):318-346.
[45] WINKER C D.Clastic shelf margins of the post-Comanchean Gulf of Mexico:implications for deep-water sedimentation[M]//Austin Marriott Hotel.Characteristics of gulf basin deep-water sediments and their exploration potential.Austin:SEPM Society for Sedimentary Geology,1984:109-120.
[46] GALLOWAY W E,BEBOUT D G,FISHER W L,et al.Cenozoic[M]//SALVADOR A.The Gulf of Mexico Basin.Boulder:Geological Society of America,1991:245-324.
[47] PANG Xiongqi,LIU Keyu,MA Zhongzhen,et al.Dynamic field division of hydrocarbon migration,accumulation and hydrocarbon enrichment rules in sedimentary basins[J].Acta Geologica Sinica:English Edition,2012,86(6):1559-1592.
[48] 庞雄奇,姜振学,黄捍东,等.叠复连续油气藏成因机制、发育模式及分布预测[J].石油学报,2014,35(5):795-828.
PANG Xiongqi,JIANG Zhenxue,HUANG Handong,et al.Formation mechanisms,distribution models,and prediction of superimposed,continuous hydrocarbon reservoirs[J].Acta Petrolei Sinica,2014,35(5):795-828.
[49] TISSOT B P,WELTE D H.Petroleum formation and occurrence[M].Berlin,Heidelberg:Springer,2013:215-228.
[50] 郝芳.超压盆地生烃作用动力学与油气成藏机理[M].北京:科学出版社,2005:73-96.
HAO Fang.Kinetics of hydrocarbon generation and mechanisms of petroleum accumulation in overpressured basins[M].Beijing:Science Press,2005:73-96.
[51] 郝芳,邹华耀,方勇,等.超压环境有机质热演化和生烃作用机理[J].石油学报,2006,27(5):9-18.
HAO Fang,ZOU Huayao,FANG Yong,et al.Kinetics of organic matter maturation and hydrocarbon generation in overpressure environment[J].Acta Petrolei Sinica,2006,27(5):9-18.
[52] 庞礴,董月霞,陈迪,等.含油气盆地砂岩目的层油气富集主控因素与基本模式——以渤海湾盆地南堡凹陷新近系砂岩油气藏为例[J].石油学报,2019,40(5):519-531.
PANG Bo,DONG Yuexia,CHEN Di,et al.Main controlling factors and basic model for hydrocarbon enrichment in the sandstone target layer of petroliferous basin:a case study of Neogene sandstone reservoirs in Nanpu sag,Bohai Bay Basin[J]Acta Petrolei Sinica,2019,40(5):519-531.
[53] PRICE L C.Thermal stability of hydrocarbons in nature:limits,evidence,characteristics,and possible controls[J].Geochimica et Cosmochimica Acta,1993,57(14):3261-3280.
[54] 柳广弟.石油地质学[M].4版.北京:石油工业出版社,2009.
LIU Guangdi.Petroleum geology[M].4th ed.Beijing:Petroleum Industry Press,2009.
[55] JONES P H.Geothermal resources of the northern Gulf of Mexico Basin[J]. Geothermics,1970,2:14-26.
[56] PANG Xiongqi,JIA Chengzao,ZHANG Kun,et al.The dead line for oil and gas and implication for fossil resource prediction[J].Earth System Science Data,2020,12(1):577-590.
[57] 汪集旸,胡圣标,庞忠和,等.中国大陆干热岩地热资源潜力评估[J].科技导报,2012,30(32):25-31.
WANG Jiyang,HU Shengbiao,PANG Zhonghe,et al.Estimate of geothermal resources potential for hot dry rock in the continental area of China[J].Science & Technology Review,2012,30(32):25-31.
[58] BOWERS G L.Pore pressure estimation from velocity data:accounting for overpressure mechanisms besides undercompaction[J].SPE Drilling & Completion,1995,10(2):89-95.
[59] SWARBRICK R E,OSBORNE M J,YARDLEY G S.Comparison of overpressure magnitude resulting from the main generating mechanisms[M]//HUFFMAN A,BOWERS G.Pressure regimes in sedimentary basins and their prediction.Tulsa,Oklahoma:AAPG,2001:1-13.
[60] TINGAY M R P,MORLEY C K,LAIRD A,et al.Evidence for overpressure generation by kerogen-to-gas maturation in the northern Malay Basin[J].AAPG Bulletin,2013,97(4):639-672.
[61] WEBSTER M,O'CONNOR S,PINDAR B,et al.Overpressures in the Taranaki Basin:distribution,causes,and implications for exploration[J].AAPG Bulletin,2011,95(3):339-370.
[62] 侯志强,张书平,李军,等.西湖凹陷中部西斜坡地区超压成因机制[J].石油学报,2019,40(9):1059-1068.
HOU Zhiqiang,ZHANG Shuping,LI Jun,et al.Genetic mechanism of overpressures in the west slope of central Xihu sag[J].Acta Petrolei Sinica,2019,40(9):1059-1068.
[63] YARDLEY G S,SWARBRICK R E.Lateral transfer:a source of additional overpressure?[J].Marine and Petroleum Geology,2000,17(4):523-537.
[64] TINGAY M R P,HILLIS R R,SWARBRICK R E,et al.'Vertically transferred' overpressures in Brunei:evidence for a new mechanism for the formation of high-magnitude overpressure[J].Geology,2007,35(11):1023-1026.
[65] 石昕,戴金星,赵文智.深层油气藏勘探前景分析[J].中国石油勘探,2005,10(1):1-10.
SHI Xin,DAI Jinxing,ZHAO Wenzhi.Analysis of deep oil and gas reservoirs exploration prospect[J].China Petroleum Exploration,2005,10(1):1-10.
[66] U.S.Energy Information Administration.Top 100 U.S.oil and gas fields[R].Washington,DC:U.S.Energy Information Administration,2015.

深层—超深层高孔高渗碎屑岩油气藏地质特征、形成条件及成藏模式——以墨西哥湾盆地为例

Geological characteristics, formation conditions and accumulation model of deep and ultra-deep,high-porosity and high-permeability clastic reservoirs: a case study of Gulf of Mexico Basin

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