南海深水盆地油气地质特征及勘探方向

在深入调研南海深水盆地油气地质条件的基础上,系统分析了油气分布规律和成藏主控因素,明确了油气资源潜力和有利勘探方向,旨在为南海深水油气勘探决策提供科学依据。研究结果表明:南海深水盆地发育在非典型边缘海大陆边缘,其石油地质条件具有特殊性,油气分布特征存在显著的南北差异。其中,南海北部深水的珠江口盆地和琼东南盆地,以构造圈闭型油气藏为主;南海中南部深水的曾母盆地南部和文莱-沙巴盆地,主要为构造圈闭型油气藏,曾母盆地北部以岩性油气藏(生物礁滩型油气藏)为主,万安盆地主要为构造圈闭型和基岩潜山型油气藏。南海北部深水盆地和中南部深水盆地的烃源岩、储盖和圈闭等油气地质特征表明,南海深水盆地具有巨大的油气勘探潜力。南海深水的有利勘探方向为:①琼东南盆地乐东-陵水凹陷的中央峡谷、陵南斜坡带,松南-宝岛凹陷的反转构造带,宝岛凹陷北坡海底扇,长昌凹陷的环A洼圈闭带(海底扇);珠江口盆地白云凹陷的主洼深水扇、主洼两翼、西南断阶带,荔湾凹陷的深水扇。②南海中南部深水盆地的文莱-沙巴、曾母和万安盆地。     

琼东南盆地深水区东区凹陷带结构构造及其演化特征

琼东南盆地深水区东区凹陷带,即松南—宝岛—长昌凹陷,位于琼东南盆地中央坳陷东端。在大量地震资料解释的基础上,对38条主要断层进行了详细分析。获得以下认识:(1)琼东南盆地深水区东区凹陷带平面上表现为近EW向展布的平行四边形,剖面结构表现为自西向东由半地堑—不对称的地堑—半地堑有规律变化。(2)琼东南盆地深水区东区凹陷带断裂系统可划分控制凹陷边界断层、控制洼陷沉积中心断层和调节性断层3类。(3)琼东南盆地深水区东区凹陷带古近纪时期受到太平洋板块俯冲和南海海盆扩张的双重影响,构造应力场发生NW—SE→SN转变。构造演化可划分为3个阶段:～32Ma,应力场以区域性NW—SE向伸展为主,断裂系统以NE—SW向为主,控制凹陷边界;32～26Ma,以南海海盆近SN向拉张应力场为主,断裂系统以NWW—SEE向为主,断层活动控制凹陷沉积中心;26～Ma,区域性伸展与南海海盆扩张应力均逐渐减弱,NE—SW向和NWW—SEE向断裂继承性发育。(4)琼东南盆地深水区东区凹陷带内部主要断层在渐新统崖城组和陵水组沉积时期活动速率快,地形高差大、沉积水体深、沉积厚度大,控制了崖城组和陵水组的大规模沉积,有利于烃源岩的发育。圈闭以受断层控制的断鼻和断块为主,长昌主洼凹中隆起带发育2个最为理想的构造圈闭。     

琼东南盆地深水区陵南低凸起古潜山油气成藏条件

基于琼东南盆地深水区砂岩储层整体欠发育这一地质背景,综合评价了陵南低凸起古潜山领域油气成藏地质条件,并对该区的成藏模式与特征进行了预测和讨论。研究表明,陵南低凸起古潜山由邻近的乐东-陵水富生烃凹陷供烃,被成熟烃源岩包围,具有中生界花岗岩潜山储层与新近系厚层海相泥岩构成的储盖组合,发育大型沟源断裂及与之配置较好的大型继承性构造脊等构成畅通的运聚系统,具有源储压差大、近源直接充注的优势。相较已获勘探成功的松南低凸起古潜山油气藏,其成藏条件更为优越,成藏模式与越南白虎大型古潜山油田和渤海渤中19-6大型古潜山凝析气田具有一定的可类比性。陵南低凸起的石油地质条件切合琼东南盆地深水区“富泥贫砂”的地质背景,可形成大规模、连片性古潜山油气藏,是琼东南盆地中央峡谷水道领域之外又一有利的深水油气勘探新领域。     

琼东南盆地深水区生物礁生长环境及分布特征分析

生物礁储层是一种典型的油气储层,具有非常大的油气勘探潜力.位于南海北部大陆边缘的琼东南盆地,在形成演化过程中出现了有利于生物礁发育的环境.盆地南部深水区远离物源,在构造演化过程中产生了较多的构造隆起,在这些构造隆起的周缘适合生物礁的发育.通过地震资料解释认为,琼东南盆地南部深水区发育有规模大小不等的生物礁,而且这些生物礁的发育与构造演化的阶段可以对应起来,应具有较好的油气勘探潜力.     

东格陵兰盆地油气资源评价

东格陵兰盆地陆上和近海地区是目前北极与深水油气勘探的热点地区,但油气勘探程度和资源认识程度低。美国地质调查局(2000、2007年)油气资源评价结果表明该区具有很大的油气资源潜力,同时油气勘探具有高风险和不确定性。通过收集整理东格陵兰盆地、北海盆地油气地质资料及油气田勘探开发数据,从区域上对两个地区的油气成藏条件进行了对比,并采用地球化学方法与类比法,评价了东格陵兰盆地的油气资源潜力。东格陵兰盆地属于晚古生代—中生代的裂谷盆地,呈现两坳一隆的构造格局,与挪威陆架盆地在进入被动陆缘阶段之前具有相同的地质发育过程,沉积环境类似,共同经历古生代和中生代裂谷及裂后的热沉降。东格陵兰盆地发育晚古生代湖相烃源岩、上侏罗统海相烃源岩,储层主要为中侏罗统浅海相砂岩和白垩系深海浊积砂岩,圈闭类型主要为伸展构造圈闭、地垒断块圈闭、盐构造圈闭以及地层圈闭等。东格陵兰盆地油气成藏条件优越,油气资源潜力较大,具有较好的勘探前景。在影响东格陵兰盆地油气资源认识的诸多地质因素中,有利圈闭类型、必要数量的烃源岩以及油气生成条件和适当埋藏史还待进一步证实。     

琼东南盆地深水区浅层运聚系统及其对天然气水合物成藏的控制

以琼东南盆地连片三维地震资料为基础,精细识别盆地浅层多种类型运移通道,系统总结了盆地深水区浅层运聚系统发育特征,并探讨其对天然气水合物成藏的控制,预测了天然气水合物有利目标区。研究结果表明:琼东南盆地浅层运移通道主要包括断层、气烟囱、裂隙、大型侵蚀不整合面和盆缘大型储集体,多种类型运移通道空间上相互组合,共同构建成盆地浅层流体运聚系统;不同区域浅层流体运移通道发育程度不一样,陵南-松南低凸起浅层流体运移通道最为发育,中央坳陷发育程度次之,浅水区相对不发育;琼东南盆地深水区浅层流体运聚系统控制着天然气水合物的分布,对中深层天然气勘探也具有重要的指示作用。总之,琼东南盆地浅层流体运移通道较发育,其中最为发育的陵南-松南低凸起是盆地天然气水合物规模成藏最为有利的场所,松南-宝岛凹陷陆坡区也具备优越的水合物成藏条件。     

北部湾盆地迈陈凹陷油气成藏条件分析

迈陈凹陷位于北部湾盆地东北部，勘探程度低，对油气成藏条件缺乏系统和深入的认识。以油气地质理论为指导，在构造和沉积地层特征研究的基础上，重点分析了烃源岩、储集层、圈闭及输导介质等油气成藏的基本要素，认为迈陈凹陷拥有较好的烃源岩，发育多套储集层、多种类型圈闭和复合的输导介质，具备油气藏形成的基本条件，具有广阔的油气勘探前景。     

南海北部陆缘盆地与坎坡斯盆地

我国南海是西太平洋最大的边缘海,其北部陆缘盆地深水区位于琼东南与珠江口盆地南侧.通过对该地区烃源条件、储层条件、圈闭条件及成藏模式等的初步研究,认为其具有良好的石油地质条件,有效勘探面积和勘探潜力巨大,具有良好的勘探前景.坎坡斯盆地位于巴西大西洋大陆边缘,是一个中生代到古新近纪含油气盆地,其内部的Garoupa, Carapeba, Namorado, Roncador, Marlim等深水油田的地质储量十分丰富,随着各个油田开发的深入,对该地区的深水含油气系统有了更加清晰的了解.本文通过两个地区在构造演化,烃源条件,储层条件,圈闭条件以及成藏模式的对比研究,对南海北部陆缘盆地深水区有了进一步的认识.     

北部湾盆地涠西南凹陷油气成藏条件分析

涠西南凹陷位于北部湾盆地西南部,发育有多个油气田(含油气构造)。以油气地质理论为指导,在构造和沉积地层特征研究的基础上,重点分析了烃源岩、储集层、圈闭及输导介质等油气成藏的基本要素,认为涠西南凹陷拥有较好的烃源岩、发育多套储集层、多种类型圈闭和复合的输导介质,具备油气藏形成的基本条件,具有广阔的油气勘探前景。     

东格陵兰陆架油气地质特征及勘探潜力

东格陵兰陆架深水盆地群是目前深水油气勘探的热点地区之一,但勘探程度还很低。以收集到的东格陵兰陆架的最新地质基础资料和油气田资料为依据研究发现,研究区主力烃源岩为上侏罗统Hareelv组海相页岩和下侏罗统KapStewart组三角洲相泥页岩,主力储层为中侏罗统浅海相砂岩和白垩系深海浊积砂岩,发育陆生海储海盖型和海生海储海盖型两大类生储盖组合,圈闭主要为伸展构造圈闭、地垒断块圈闭、盐构造圈闭以及地层圈闭等。东格陵兰陆架油气成藏条件优越,资源潜力巨大,储量约为323.4亿桶油当量,待发现油气田约300个。     

Structural characteristics of central depression belt in deep-water area of the Qiongdongnan Basin and the hydrocarbon discovery of Songnan low bulge

The Qiongdongnan Basin has the first proprietary high-yield gas field in deep-water areas of China and makes the significant breakthroughs in oil and gas exploration. The central depression belt of deep-water area in the Qiongdongnan Basin is constituted by five sags, i.e. Ledong Sag, Lingshui Sag, Songnan Sag, Baodao Sag and Changchang Sag. It is a Cenozoic extensional basin with the basement of pre-Paleogene as a whole. The structural research in central depression belt of deep-water area in the Qiongdongnan Basin has the important meaning in solving the basic geological problems, and improving the exploration of oil and gas of this basin. The seismic interpretation and structural analysis in this article was operated with the 3D seismic of about 1.5×10~4 km~2 and the 2D seismic of about 1×10~4 km. Eighteen sampling points were selected to calculate the fault activity rates of the No.2 Fault. The deposition rate was calculated by the ratio of residual formation thickness to deposition time scale. The paleo-geomorphic restoration was obtained by residual thickness method and impression method. The faults in the central depression belt of deep-water area of this basin were mainly developed during Paleogene, and chiefly trend in NE–SW, E–W and NW–SE directions. The architectures of these sags change regularly from east to west: the asymmetric grabens are developed in the Ledong Sag, western Lingshui Sag, eastern Baodao Sag, and western Changchang Sag; half-grabens are developed in the Songnan Sag, eastern Lingshui Sag, and eastern Changchang Sag. The tectonic evolution history in deep-water area of this basin can be divided into three stages,i.e. faulted-depression stage, thermal subsidence stage, and neotectonic stage. The Ledong-Lingshui sags, near the Red River Fault, developed large-scale sedimentary and subsidence by the uplift of Qinghai-Tibet Plateau during neotectonic stage. The Baodao-Changchang sags, near the northwest oceanic sub-basin, developed the large-scale magmatic activities and the transition of stress direction by the expansion of the South China Sea. The east sag belt and west sag belt of the deep-water area in the Qiongdongnan Basin, separated by the ancient Songnan bulge, present prominent differences in deposition filling, diaper genesis, and sag connectivity. The west sag belt has the advantages in high maturity, well-developed fluid diapirs and channel sand bodies, thus it has superior conditions for oil and gas migration and accumulation. The east sag belt is qualified by the abundant resources of oil and gas. The Paleogene of Songnan low bulge, located between the west sag belt and the east sag belt, is the exploration potential. The YL 8 area, located in the southwestern high part of the Songnan low bulge, is a favorable target for the future gas exploration. The Well 8-1-1 was drilled in August 2018 and obtained potential business discovery, and the Well YL8-3-1 was drilled in July 2019 and obtained the business discovery.     

Geology and hydrocarbon accumulations in the deepwater of the northwestern South China Sea——with focus on natural gas

The deepwater of the northwestern South China Sea is located in the central to southern parts of the Qiongdongnan Basin(QDN Basin),which is a key site for hydrocarbon exploration in recent years.In this study,the authors did a comprehensive analysis of gravity-magnetic data,extensive 3D seismic survey,cores and cuttings,paleontology and geochemical indexes,proposed the mechanism of natural gas origin,identified different oil and gas systems,and established the model of hydrocarbon accumulations in the deep-water region.Our basin tectonic simulation indicates that the evolution of QDN Basin was controlled by multiple-phased tectonic movements,such as Indochina-Eurasian Plate collision,Tibetan Uplift,Red River faulting and the expansion of the South China Sea which is characterized by Paleogene rifting,Neogene depression,and Eocene intensive faulting and lacustrine deposits.The drilling results show that this region is dominated by marineterrestrial transitional and neritic-bathyal facies from the early Oligocene.The Yacheng Formation of the early Oligocene is rich in organic matter and a main gas-source rock.According to the geological-geochemical data from the latest drilling wells,Lingshui,Baodao,Changchang Sags have good hydrocarbon-generating potentials,where two plays from the Paleogene and Neogene reservoirs were developed.Those reservoirs occur in central canyon structural-lithologic trap zone,Changchang marginal trap zone and southern fault terrace of Baodao Sag.Among them,the central canyon trap zone has a great potential for exploration because the various reservoirforming elements are well developed,i.e.,good coal-measure source rocks,sufficient reservoirs from the Neogene turbidity sandstone and submarine fan,faults connecting source rock and reservoirs,effective vertical migration,late stage aggregation and favorable structural–lithological composite trapping.These study results provide an important scientific basis for hydrocarbon exploration in this region,evidenced by the recent discovery of the significant commercial LS-A gas field in the central canyon of the Lingshui Sag.     

西湖凹陷油气成藏史分析

在西湖凹陷区域研究新认识的基础上，通过构造发展史、排烃史、成藏期痕检资料、岩相组合等资料，重新认识西湖凹陷新生代盆地发展过程中圈闭（地层、构造）形成时间、烃源岩排烃时间、已发现油气藏成藏时间、多种疏导方式及形成时间以及对油气藏的破坏事件发生时间，推演西湖凹陷成藏史发展过程。结合新的油气成藏认识，提出今后工作方向的几点思考意见。     

珠江口盆地文昌A凹陷油气差异分布特征

在烃源岩分布特征、有机质丰度、类型和成熟度分析的基础上,运用含油气盆地数值模拟技术,定量恢复了烃源岩热成熟演化史,探讨了油气差异分布特征。研究表明,文昌A凹陷各层系烃源岩分布广,厚度大,有机质丰度高;有机质类型文昌组偏Ⅱ1型,恩平组偏Ⅲ型,二者现今多处于高成熟—过成熟阶段。凹陷内烃源岩成熟时间早(文昌组约45.5Ma),现今成熟度高,以干气生成为主;凹陷边缘烃源岩成熟时间较晚(文昌组约30.0Ma),现今成熟度相对较低,以石油生成为主。凹陷现今油气差异分布的格局受制于有机质类型差异和热演化史不同,且下一步油气勘探方向,凹陷内以天然气为主,凹陷边缘以石油为主。     

歧口凹陷东北环天然气成藏条件与勘探领域

歧口凹陷是渤海湾盆地重要的生气凹陷,存在石炭-二叠系和古近系沙河街组两套生气层系,凹陷东北环紧邻歧口凹陷主洼,具备形成大型天然气田的物质基础。在古近纪沉积时期受三个方向物源的影响,储盖组合较发育,沙河街组的超压又较好的保存了储层物性。通过对构造特征、沉积体系和油气运移条件分析,认为凹陷东北环深层构造圈闭、沙垒田凸起西翼倾没端地层圈闭和深层岩性圈闭是该区天然气勘探的重要领域和方向。     

通王断裂带沙河街组油气成藏主控因素研究

通王断裂带地区位于济阳坳陷东营凹陷南斜坡东部，沙河街组是本区的主要含油层系。通过烃源岩分析、储集层类型划分、孔隙流体动力场的描述、优质输导体系类型及断裂构造特征的研究，认为牛庄洼陷烃源岩主要为沙四上和沙三段深湖相一半深湖相暗色泥岩、油页岩，油气以生油洼陷为中心，呈环状或半环状分布；沙三段大型三角洲相储集砂体、沙四段中上部的滨浅湖近岸砂坝、远岸砂坝和席状砂岩储层是主要储集层类型；砂体一断层类输导体系是本区优质输导体系，牛庄洼陷北部发育的高压型复式温压系统，使油气顺着断层、砂体向南部通王断裂带常压常温和常压高温区运移。通王断裂带的油气藏主要是受断裂控制的构造油气藏，王家岗油田往西的中浅层是断层类油藏的有利地区，王家岗地区北部和陈官庄地区的西北部，是沙三段隐蔽油气藏以及断层-岩性复合型油气藏勘探的有利勘探地区。     

琼东南盆地深水区L18气田上新统地层圈闭气田形成条件及成藏模式

近期在琼东南盆地超深水区发现了L18气田上新统地层圈闭气田，但在聚气背景、烃源岩、储层沉积成因及天然气输导体系等气田形成条件和成藏模式认识存在争议。通过对该气田形成条件的综合分析，认为上新世轴向古洼槽内地层圈闭、陵水凹陷东洼下渐新统崖城组浅海相烃源岩、上新统限制型重力流砂岩储层和渐新统-中新统断裂垂向沟源通道是形成上新统地层圈闭气田的4个基本条件。中中新世以来盆地中央继承性发育轴向古洼槽和限制型重力流沉积，随着后期地层沉积迁移、差异压实作用，上新统莺歌海组砂岩顶面在轴向洼槽内起伏，并被周边泥岩封盖、封堵，形成了地层圈闭；约3.4 Ma BP，陵水凹陷东洼下渐新统崖城组浅海相烃源岩生成了成熟天然气，沿渐新统-中新统断裂向上运移到上新统莺歌海组重力流沉积砂岩中，再侧向运移至地层圈闭中聚集成藏，具有"烃源岩、圈闭、断裂+砂岩输导层"三要素控藏的上新统地层圈闭成藏模式。     

渤海湾及沿岸盆地的构造格局

渤海湾及沿岸盆地面积约20万平方公里,包括河北省,山东省北部和西部、辽宁省南部、河南省北部、天津市和北京市等陆地面积约12万7千平方公里,渤海海域面积为7万多平方公里。陆地面积大部被第四纪冲积层所覆盖。渤海最大深度为70米,平均深度为18米。这是一个大型的第三纪断陷-坳陷沉积盆地,是继大庆油田开发之后,在我国东部地区所开发的另一个重要的含油气盆地(图1)。     

Distribution characteristics of delta reservoirs reshaped by bottom currents: A case study from the second member of the Yinggehai Formation in the DF1-1 gas field,Yinggehai Basin,South China Sea

The Dongfang1-1 gas field (DF1-1) in the Yinggehai Basin is currently the largest offshore self-developed gas field in China and is rich in oil and gas resources. The second member of the Pliocene Yinggehai Formation (YGHF) is the main gas-producing formation and is composed of various sedimentary types; however, a clear understanding of the sedimentary types and development patterns is lacking. Here, typical lithofacies, logging facies and seismic facies types and characteristics of the YGHF are identified based on high-precision 3D seismic data combined with drilling, logging, analysis and testing data. Based on 3D seismic interpretation and attribute analysis, the origin of high-amplitude reflections is clarified, and the main types and evolution characteristics of sedimentary facies are identified. Taking gas formation upper II (IIU) as an example, the plane distribution of the delta front and bottom current channel is determined; finally, a comprehensive sedimentary model of the YGHF second member is established. This second member is a shallowly buried “bright spot” gas reservoir with weak compaction. The velocity of sandstone is slightly lower than that of mudstone, and the reflection has medium amplitude when there is no gas. The velocity of sandstone decreases considerably after gas accumulation, resulting in an increase in the wave impedance difference and high-amplitude (bright spot) reflection between sandstone and mudstone; the range of high amplitudes is consistent with that of gas-bearing traps. The distribution of gas reservoirs is obviously controlled by dome-shaped diapir structural traps, and diapir faults are channels through which natural gas from underlying Miocene source rocks can enter traps. The study area is a delta front deposit developed on a shallow sea shelf. The lithologies of the reservoir are mainly composed of very fine sand and coarse silt, and a variety of sedimentary structural types reflect a shallow sea delta environment; upward thickening funnel type, strong toothed bell type and toothed funnel type logging facies are developed. In total, 4 stages of delta front sand bodies (corresponding to progradational reflection seismic facies) derived from the Red River and Blue River in Vietnam have developed in the second member of the YGHF; these sand bodies are dated to 1.5 Ma and correspond to four gas formations. During sedimentation, many bottom current channels (corresponding to channel fill seismic facies) formed, which interacted with the superposed progradational reflections. When the provenance supply was strong in the northwest, the area was dominated by a large set of delta front deposits. In the period of relative sea level rise, surface bottom currents parallel to the coastline were dominant, and undercutting erosion was obvious, forming multistage superimposed erosion troughs. Three large bottom current channels that developed in the late sedimentary period of gas formation IIU are the most typical.