Coupling relationship and genetic mechanisms of shelf-edge delta and deep-water fan source-to-sink:A case study in Paleogene Zhuhai Formation in south subsag of Baiyun Sag,Pearl River Mouth Basin,China

The coupling relationship between shelf-edge deltas and deep-water fan sand bodies is a hot and cutting-edge field of international sedimentology and deep-water oil and gas exploration.Based on the newly acquired high-resolution 3D seismic,logging and core data of Pearl River Mouth Basin(PRMB),this paper dissected the shelf-edge delta to deep-water fan(SEDDF)depositional system in the Oligocene Zhuhai Formation of Paleogene in south subsag of Baiyun Sag,and revealed the complex coupling relationship from the continental shelf edge to deep-water fan sedimentation and its genetic mechanisms.The results show that during the deposition of the fourth to first members of the Zhuhai Formation,the scale of the SEDDF depositional system in the study area showed a pattern of first increasing and then decreasing,with deep-water fan developed in the third to first members and the largest plane distribution scale developed in the late stage of the second member.Based on the development of SEDDF depositional system along the source direction,three types of coupling relationships are divided,namely,deltas that are linked downdip to fans,deltas that lack downdip fans and fans that lack updip coeval deltas,with different depositional characteristics and genetic mechanisms.(1)Deltas that are linked downdip to fans:with the development of shelf-edge deltas in the shelf area and deep-water fans in the downdip slope area,and the strong source supply and relative sea level decline are the two key factors which control the development of this type of source-to-sink(S2S).The development of channels on the continental shelf edge is conducive to the formation of this type of S2S system even with weak source supply and high sea level.(2)Deltas that lack downdip fans:with the development of shelf edge deltas in shelf area,while deep water fans are not developed in the downdip slope area.The lack of“sources”and“channels”,and fluid transformation are the three main reasons for the formation of this type of S2S system.(3)Fans that lack updip coeval deltas:with the development of deep-water fans in continental slope area and the absence of updip coeval shelf edge deltas,which is jointly controlled by the coupling of fluid transformation at the shelf edge and the“channels”in the continental slope area.

Deep-water Depositional Features of Miocene Zhujiang Formation in Baiyun Sag,Pearl River Mouth Basin

Eleven lithofacies and five lithofacies associations were indentified in the Miocene Zhujiang Formation on the basis of detailed core analysis. It could he determined that three depositional types developed, namely submarine fan, basin and deep-water traction current. Six microfacies were further recognized within the fan, including main channels in the inner fan, distributary channels in the middle fan, inter-channels, levees and the outer fan. The lower Zhujiang Formation, mainly sandstone associations, was inner fan and inner-middle fan deposits of the basin fan and the slope fan. The middle part, mainly mudstone associations, was outer fan deposits. With the transgression, the submarine fan was finally replaced by the basinal pelagic deposits which were dominated by mudstone associations, siltstone associations, and deep-water limestone associations. During the weak gravity flow activity, the lower channels, the middle-upper outer fans and basin deposits were strongly modified by the deep-water traction current. The identification of the deep-water traction deposition in Miocene Zhujiang Formation would be of great importance. It could be inferred that the deep- water traction current had been existing after the shelf-break formation since the Late Oligocene （23.8 Ma） in the Baiyun sag, influencing and controlling the sediment composition, the distribution, and depositional processes. It would provide great enlightenment to the paleo-oceanic current circulation in the northern South China Sea.

Characteristics of the turbidite fan in the Wenchang Formation of the Enping Sag, Pearl River Mouth Basin, China and its hydrocarbon significance

A turbidite fan in the Eocene upper Wenchang Formation in the Enping Sag, Pearl River Mouth Basin （PRMB） has been studied using seismic, logging and borehole data. The fan is characterized by parallel progradation on the dip seismic profile and is mound-shaped or lenticular-shaped on the strike seismic profile. The study of the core and logging data from well EP17-3-1, which is located in the front side of the turbidite fan, shows that this fan is a set of normal grading sand beds, interbedded within thick dark grey mudstones of semi-deep to deep lake deposits in the Wenchang Formation. The fan is interpreted as a sand/mud-rich turbidite fan that has an area of over 140 km2 and a maximum thickness of over 340 m. Combined with a study of the regional geological background and previous provenance analysis of the Eocene Wenchang Formation, the main potential provenances for the turbidite fan are considered to be the Panyu low-uplift and northern fault terrace zone. The Enping Sag is considered to be a half graben-like basin whose north side is faulted and whose south side is overlapped. Basement subsidence in the Eocene was mainly controlled by boundary faults which dip relatively steeply on the north side, causing the subsidence center of the Enping Sag in this stage to be close to the north boundary faults. Sustained faults developed in the Enping Sag during the Eocene caused an increase of the relative height difference between the north and the south uplift zone in the Enping Sag. Affected by the second episode of the Zhuqiong movement （39-36 Ma） in late Eocene, sediments which had accumulated on the Panyu low-uplift zone were triggered and moved toward the subsidence center of the Enping Sag and formed the turbidite fan. The second episode of the Zhuqiong movement is the most important triggering factor for the formation of the turbidite fan in the Wenchang Formation. Seismic attribute characterization shows that the low frequency energy is enhanced and high frequency energy is weakened when seismic waves propagate through the oil-bearing zone in this fan. Amplitude versus offset （AVO） anomalies are observed in the seismic data and abnormally high pressure is encountered. The turbidite fan in the Wenchang Formation has provided important information for sedimentary evolution in deep layers of the Enping Sag and pointed to a new direction for the hydrocarbon exploration in the study area.

南海东部深水浊积砂岩气藏储层精细描述与连通性研究

南海东部深水区油气资源丰富,深水重力流浊积砂岩展布复杂,砂体构型期次划分、构型单元叠置样式和连通关系直接制约气田的布井开发。以南海东部深水L气田为例开展研究,基于地震沉积学方法,运用沉积模式研究、复合水道体系构型及建模表征方法,开展了基于南海深水重力流复合砂体解剖,建立了本海域深水气田浊积水道复合砂体构型划分方案,开展了单期构型砂体空间演化和展布规律研究。研究成果表明:南海深水L气田浊积水道可划分为复合浊积体、复合水道和单一水道等3个级次,在气田内部平面上发育4条复合水道,纵向上发育2期河道,建立复合水道内部的沉积演化规律,明确了水道间的连通关系,并结合动态生产验证了连通关系的合理性,成功指导相邻B气田部署1口水平井,最高日产达130万方,生产效果较好。研究成果对推动周边气田开发及潜力勘探具有一定借鉴和启示意义。

陆架边缘三角洲-深水扇源汇耦合关系及成因机制——以珠江口盆地白云南洼古近系珠海组为例

基于珠江口盆地新采集处理的三维地震资料、钻测井和岩心资料,精细解剖白云南洼古近系渐新统珠海组陆架边缘三角洲-深水扇(简称“洲-扇”),以揭示陆架边缘到深水扇沉积复杂的耦合关系和成因机制。研究结果表明,珠海组四段—一段沉积时期,研究区“洲-扇”沉积体系规模具有先增大后减小的规律,珠海组三段—一段沉积早期深水扇发育,珠海组二段沉积晚期平面分布规模最大。依据顺物源方向洲-扇发育程度的不同,划分出“有洲有扇、有洲无扇、无洲有扇”3种不同类型的洲-扇耦合关系。(1)“有洲有扇”型的陆架区发育陆架边缘三角洲,其下倾方向的陆坡区深水扇发育,强物源供给和相对海平面下降是主控该类型洲-扇系统发育的两大关键因素,而陆架边缘水道的发育有利于在弱物源供给及相对海平面上升时期仍能形成该类型源汇系统。(2)“有洲无扇”型的陆架区发育陆架边缘三角洲,其下倾方向的陆坡区却不发育深水扇,缺“源”、少“渠”和流体改造是形成该类型的3大主要原因。(3)“无洲有扇”型的陆坡区发育深水扇,但溯源其上倾方向陆架区不发育陆架边缘三角洲,陆架边缘的流体改造和陆坡区渠道通畅(水道发育)两者相互耦合共同控制其形成。

珠江口盆地深水气田储层差异及主控因素

为了分析珠江口盆地荔湾气区同一深水盆底扇两相邻气田的储层物性差异及主控因素,综合利用铸体薄片、扫描电镜、物性及压汞等分析资料,对2个气田的岩石组分、微观孔隙结构和宏观物性特征进行对比分析,探讨沉积及成岩对储层质量差异的控制作用。研究结果表明:1)储层质量宏观上受控于沉积作用,A气田位于扇体远端,粒度较细,分选好;B气田靠近扇根位置,粒度较粗,分选差,粒间充填泥质杂基,沉积组分差异对储层物性有一定影响。2)造成储层质量差异的主要原因是受不同埋深影响引起的差异化成岩作用。受深埋藏强压实作用,塑性组分含量高的储层,粒间泥质杂基易挤压变形,降低储层的原生孔隙体积;黏土矿物中伊利石和伊/蒙混层多呈丝缕/丝片状充填于粒间和次生孔隙中,导致储层渗透性大幅度降低。研究成果对区域深水盆底扇的油气勘探开发具有一定借鉴指导意义。

南海珠江深水扇系统的形成模式

论述了国际上深水扇系统沉积模式建立的历程,基于国外学者建立的深水扇沉积模式,分析了珠江深水扇系统的形成与沉积特征,将南海深水扇系统的主控因素概括为一球五源,应用"源—渠—汇"三级次系统,建立了有别于经典沉积模式的珠江深水扇系统沉积模式。

深水扇沉积研究现状和展望——以珠江口盆地白云凹陷珠江深水扇系统为例

与深水扇有关的储层将处于油气勘探和生产的最前沿。虽然深水扇沉积作用的研究已经取得了一定的进展,但目前国内外对其地质概念和沉积模式等方面的认识仍存在较大分歧。在国内外研究进展的基础上,结合我国南海北部珠江口盆地白云凹陷珠江深水扇系统的沉积特征,文中详细地描述了深水扇沉积体系中下切水道及其充填序列、水道、天然堤—溢岸及叶状体的沉积特征,具体地阐述了深水扇的层序发育特点及层序界面的识别标志。

南海珠江口盆地深水扇系统的发现

深水扇系统已成为近 2 0年来国际石油产量与储量增长的主体。对南海珠江口盆地层序地层学的研究和分析发现 ,在盆地内面积最大、最具生烃潜力的白云凹陷发育有大批相互叠置的低水位深水扇。基于勘探与研究成果 ,通过剖析典型高分辨二维地震资料 ,证实白云深水凹陷是自 3 0Ma以来古珠江水系的沉积中心 ,与全球海平面变化周期相协调。在对应的各个三级层序的低水位发展阶段形成深水沉积体系 ,并具备独特的地震相组合结构。深水扇系统广布于受同沉积断层控制的古陆架坡折带及其下倾方向。

珠江口盆地13.8Ma陆架边缘三角洲与陆坡深水扇的“源汇”关系

揭示南海北部被动大陆边缘盆地浅海陆架与深水陆坡之间的沉积响应关系,在等时地层格架内对陆架三角洲、上陆坡复合水道和陆坡重力流沉积进行综合分析。研究结果表明:相对海平面变化、陆架多级坡折演化、陆源碎屑供给强度以及陆架海洋水动力作用等四大因素控制着陆架陆坡体系的发育;珠江口盆地中新统韩江组13.8 Ma形成的界面为三级层序界面,该时期低位域晚期发育陆架边缘三角洲,三角洲前缘带主体分布在白云凹陷北坡的陆架坡折处,随着物源供给,前缘带不断进积,陆架向陆坡方向生长,在多级坡折、坡度变化以及沉积物自身重力影响下,前缘带沉积物由牵引流搬运向重力流搬运转化,在陆坡复合水道搬运通道的作用下向白云凹陷深水区内再沉积,形成低位域晚期多坡度控制的滑塌体、碎屑流浊流深水扇沉积,构成南海北部珠江口盆地特殊的陆架陆坡"源汇"响应系统;该沉积响应具有短暂性、突发性和连续性等特点。

南海珠江深水扇系统的沉积构造背景分析

从深水扇系统的观点出发,主要基于对最近所采集的穿越整个白云凹陷的700余公里长电缆深反射（深达14 s）地震资料综合解释,结合南海大洋钻探的成果,对南海珠江深水扇系统沉积的构造背景特征进行了综合分析.研究发现：白云主凹在早中新世-中中新世期间（即大约距今25～10 Ma）是一个因坳陷期盆地基底的持续沉降及其相关断裂活动而形成的南海北部陆缘上的斜坡内盆地;白云主凹这个“斜坡内盆地”有别于世界上其它位于被动大陆边缘背景中（如西非近海、巴西近海、墨西哥湾）的斜坡内盆地;海平面变化、沉积物通量变化、构造活动等地质营力都在斜坡内盆地的构造背景上对南海珠江深水扇系统在不同时期产生了不同程度的重要影响.简言之,斜坡内盆地成就了南海珠江深水扇系统.这为以后进一步全面深入研究南海珠江深水扇系统的形成机制、演化过程、结构特征等有着重要意义.

珠江口盆地储层特征

早渐新世晚期(30Ma)南海运动后,珠江口盆地大部分进入浅水陆架区,由陆相环境向海相环境过渡,古近纪末(23.8Ma)白云运动后,随着海平面的不断上升,盆地整体进入海相沉积环境。珠江口盆地经历了不同的构造演化阶段,发育不同类型的储层,储层主要发育在上部的晚渐新世—第四纪海陆交互相及海相沉积中。浅水区储层主要包括三角洲砂体、陆架砂脊、滨岸砂、生物礁及扇三角洲砂体沉积,其中由古珠江大河控制的陆架三角洲—滨岸体系及生物礁是已发现油田最主要的产层;深水区储层主要包括海底扇,陆架边缘三角洲,台缘斜坡扇沉积,其中低位的海底扇砂体和陆架边缘三角洲是深水区最具潜力的勘探目标。

白云凹陷珠江组深水扇砂岩储层特征及控制因素

通过薄片鉴定,扫描电镜、物性和孔隙结构分析,对珠江口盆地白云凹陷珠江组深水扇储层特征、控制因素和分布规律展开研究。该深水扇沉积体系的储层主要为一套碎屑流沉积的灰色中-粗粒长石岩屑砂岩和中-细粒岩屑长石砂岩,储集空间以原生粒间孔为主,次为粒间溶孔和裂缝等,具有排驱压力及中值压力小,孔喉半径大、配位数高和分选好等好的孔隙结构,多数属于中-高孔高渗型储层。储层发育主要受陆架坡折带和沉积相控制,后者包括沉积微相、砂岩粒度和砂体发育规模在内的三要素。由于深水扇砂体较早地进入超压旋回,仅经历了相当于中等埋藏深度的早成岩阶段A→B期的成岩改造,对储层发育的影响不大,因此,储层预测可以砂体成因类型和发育规模为主要依据,以深水扇内扇和中扇分流水道为最有利的勘探开发目标。

珠江口盆地深水扇识别和油气成藏关键要素

近年来在层序地层学理论的指导下,在珠江口盆地白云凹陷的地震剖面上识别出各种层序界面,并进一步识别出大量深水扇沉积体,这些深水扇体由众多的盆底扇、斜坡扇、低位楔和下切水道构成。盆底扇和斜坡扇多期叠加,平面上成朵叶状,并与下切水道相连。综合分析白云深水扇的成藏条件,得出控制深水扇成藏的关键要素有两点(1)由断层、不整合面、横向连通的砂体以及流体底辟带组成的发达的输导格架,特别是能与深水扇相连的断层与流体底辟带,是深水扇油气成藏的关键所在;(2)油气运移的动力,盆地模拟结果表明,白云凹陷曾经历了三个地层压力演化旋回,超压的累积和释放对深部烃源岩的排烃并向深水扇体中运移起到了重要作用。

白云凹陷珠江组深水扇成岩作用与成岩相分析

根据铸体薄片、扫描电镜、镜质体反射率等分析资料,对珠江口盆地白云凹陷荔湾地区珠江组深水扇砂岩储层成岩作用及成岩相进行了系统研究。确定对储层起破坏作用的成岩作用主要有压实、胶结和自生矿物充填作用,起建设性成岩作用的主要有溶蚀作用。综合成岩方式的组合类型和演化序列,认为深水扇砂岩储层成岩演化主体仅进入中成岩阶段A—B期。在建立成岩演化模式的基础上,对成岩相组合特征进行了分析,划分出胶结—弱压实—弱溶蚀相、弱压实—弱胶结—强溶蚀相和中等压实—弱胶结—中等溶蚀相等3种主要成岩相类型,其中以弱压实—弱胶结—强溶蚀相砂体的物性为最好。

珠江口盆地白云凹陷中新统珠江组物源及其研究意义

南海北部陆坡深水区3Ma以来碎屑物质来源具多样性、复杂性和变化性。利用砂岩和异源生屑灰岩岩石学及泥岩稀土元素地球化学特征研究了珠江口盆地白云凹陷中新统珠江组深水扇的物源。结果表明,珠江组砂岩岩屑主要为变质岩屑和火山岩屑,并含较多深成岩屑。阴极射线下,石英以发蓝紫色—褐色光为主,长石主要发亮蓝色光。异源生屑灰岩为陆坡钙屑碎屑流沉积,来自于神狐暗沙隆起中新统碳酸盐台地。泥岩∑REE与燕山褶皱带燕山期中酸性火山岩较接近,分配模式与上地壳基本一致,并与燕山中酸性火山岩和花岗岩较接近。渐新世末,南海运动使南海海盆第二次海底扩张,并使陆架坡折带由白云凹陷南侧跳跃到凹陷北侧。该构造事件在青藏高原邻近盆地和中国东部盆地都有反映,反映可能发生了青藏高原隆升事件,使珠江组物源向西拓展。珠江期虽然存在活跃的深水牵引流,但珠江组原始物质仍应源自古珠江携带的华南沿海燕山褶皱带的中酸性火山岩、花岗岩和内陆古老的沉积—变质岩。

珠江口盆地白云凹陷珠江组海底扇深水重力流沉积特征

珠江口盆地白云凹陷珠江组油气藏以其较大的规模、典型的海底扇结构、优越的储集性和巨大的油气勘探开发前景在国内外引起高度关注。通过对白云凹陷W和H这2个气田珠江组各种原生沉积构造及古生物等相标志分析,确定了珠江组属于以深水重力流沉积为主的海底扇沉积体系;划分出内扇、中扇和外扇3个亚相,水道、水道间和前缘朵体等微相,颗粒流、碎屑流、近源浊流和远源浊流等重力流沉积类型;在对各类重力流沉积特征和分布规律进行详细分析的基础上,提出了集源、渠、汇三位一体的海底扇沉积模式。

荔湾凹陷恩平组水道—浊积扇体系沉积演化

应用地震资料对珠江口盆地荔湾凹陷恩平组地层进行地震相分析,恢复其古地貌,并结合浅层井-震对比分析,在该区发现了一个大型水道—浊积扇体系。研究结果表明:水道在平面上呈"蛇"型沿NW—SE方向展布,受物源和古地形等因素的影响,水道不同区段的剖面形态与沉积演化特征不同,上段呈现"V"型,向中、下段逐渐转变为"U"型或"W"型;根据地震反射特征将该水道—浊积扇体系划分为3期,每期水道内部发育次级小水道。早期水道以侵蚀作用为主,中期水道以侵蚀-沉积共同作用为特征,晚期水道基本为沉积作用,而且中—晚期水道广泛发育天然堤-溢岸沉积,属于典型的侵蚀-沉积型水道。分析认为,其物源来自白云凹陷北部的三角洲。该深水扇体系的发现为深水区深部地层大型储集体的寻找及油气勘探提供参考。

珠江口盆地白云深水扇特征及油气成藏主控因素

揭示中国南海北部珠江口盆地白云深水扇的时空展布和油气成藏规律.无论在理论上、还是在向深海进军的油气勘探实践上都具有十分重要的意义.以层序地层学理论为指导的地震剖面精细解释,在白云凹陷北部陆坡区发现了大量深水扇沉积体,它由众多的盆底扇、斜坡扇、低位楔和下切水道构成.盆底扇和斜坡扇多期叠加,平面上成朵叶状,并与下切水道相连.研究表明,白云深水扇成藏的主控因素包括:(1)白云凹陷具有适合油气生成的活跃烃源岩;(2)拥有包括断层、不整合面、连续分布的砂体以及流体底辟带在内的发达的输导网络;(3)低水位期发育的深水扇体与其上覆的高水位期泥岩共同形成了有利的储盖组合;(4)超压的累积和释放对深部烃源岩的排烃起到了重要作用.因此,白云深水扇具有良好的成藏条件,是珠江口盆地深水勘探的有利目标.

珠江口盆地荔湾3-1气田珠江组深水扇沉积相分析

根据已钻井取芯段岩相分析,从荔湾3-1气田珠江组深水扇沉积体系中划分出巨厚层和厚层块状砂岩相、厚层正粒序砂岩相、厚层逆粒序砂岩相、平行—板状斜层理砂岩相、滑塌变形砂岩相、薄层砂岩夹层相、薄层(粉)砂岩与泥岩互层相、厚层粉砂岩相、厚层泥岩相和层状深水灰岩相等10种岩相类型和识别出砂岩相组合、泥岩相组合、(粉)砂岩与泥岩互层相组合、粉砂岩相组合和深水灰岩相组合等5种岩相组合类型,在此基础上,从珠江组深水扇沉积体系中进一步识别出内扇主水道、中扇分支水道、水道间、天然堤—溢岸、外扇和盆地等微相类型,将珠江组下部确定为以砂岩相组合为主的盆底扇内扇和斜坡扇内-中扇沉积组合,其中内扇主水道和中扇分支水道是最有利储层发育的沉积微相。中、上部确定为以泥岩相组合为主的外扇和盆地沉积组合,具有随海侵扩大,深水扇最终被远洋所取代的沉积演化特征。