山东东营凹陷古近系碎屑岩储层特征及控制因素

通过对大量储层物性数据的分析和整理,结合薄片观察和扫描电镜分析结果,研究了不同构造背景、不同沉积类型及不同埋深的储层物性特征及其控制因素。东营凹陷近系碎屑岩储层类型多样,大多形成在冲积扇-河流、扇三角洲、近岸水下扇、深水浊积扇、三角洲前缘滑塌浊积扇以及滨浅湖滩坝等多种沉积环境中。碎屑岩储层类型主要包括砾岩、含砾砂岩、中粗砂岩、细砂岩及粉砂岩。其中中砂岩和细砂岩是最好的储层。但是不同地区、不同类型储层物性存在较大的差异。物性最好的储层为河道、（扇）三角洲前缘水下分流河道及河口坝砂体。在相同深度条件下,中央隆起带的物性最好,北部和南部次之。另外,本区随埋藏深度增加,碎屑岩储层物性逐渐变差（剔除次生孔隙的影响）。根据碎屑岩储层物性差异性分析和储层成岩演化研究结果,其储层物性主要受压实作用、碳酸盐溶蚀与胶结作用及沉积条件四大因素控制,其中压实作用、溶蚀作用及胶结作用是主要控制因素,而沉积条件对物性的影响主要表现在控制原生孔隙的发育程度,并进一步控制溶蚀、胶结等成岩作用。     

东濮凹陷沙三段致密砂岩储层裂缝形成机制及对储层物性的影响

为探讨东濮凹陷沙三段储层裂缝的发育特征、形成机制、主控因素及其对储层的影响,综合运用岩心观察、薄片鉴定、扫描电镜、流体包裹体分析等方法对裂缝进行了研究。结果表明:东濮凹陷沙三段储层中发育的裂缝按规模可分为宏观裂缝和微观裂缝两大类,按成因可分为构造缝、超压缝和成岩缝。构造缝走向以NNE向、NE向为主,其形成可分为两期,分别为40～35 Ma沙河街组沉积中后期和25～18 Ma东营组沉积末期。超压缝的形成与膏盐脱水、烃类充注和膏盐层封堵作用有关,形成于33～25 Ma东营组沉积时期。压实作用、溶解作用、收缩作用等成岩作用均可形成微裂缝。裂缝的形成序列为:早期构造缝-压裂缝-溶解缝-超压缝-收缩缝-晚期构造缝-溶解缝-压裂缝;裂缝的发育可以改善储层物性,宏观裂缝主要起渗流作用,微观裂缝既可作为有效的储集空间,又可作为酸性流体流动通道,产生次生孔隙带,提高储层孔隙度。     

伸展构造拉张量计算方法的适用性分析及在琼东南盆地的应用

文章将三种以面积平衡为原理的几何学方法应用在物理模拟拉张实验中,对比三种方法的结果与模型设计参数间的 误差,讨论了三种方法的优缺点和适用范围。其中层长守恒方法需要假设在构造变形过程中层长保持不变,通过曲线拉直 可以恢复构造各阶段拉张量和拉张总量。利用面积守恒可以计算拉张构造中滑脱层深度,面积深度法允许构造变形过程中 层长和层厚的变化,多个构造前沉积地层的面积深度拟合直线可以反映构造整体拉张量和滑脱层深度。面积守恒法在已知 构造滑脱层位置的基础上,通过同构造沉积地层可以计算出拉张活动不同阶段拉张量变化和拉张总量。结合琼东南长昌凹 陷剖面特征,面积守恒法是计算其拉张量变化最准确又有效的方法,面积守恒法应用结果确定过长昌凹陷剖面在岭头组、 崖城组和陵水组沉积阶段的拉张量分别为13.8 km、15 km和21.4 km,拉张总量为50.2 km,拉张率为42.7%。三种方法在物 理模拟实验和琼东南盆地中的应用结果表明,在伸张构造中由于剪切变形作用,基于面积守恒的方法优于层长守恒的方 法。面积深度法利用构造前沉积地层的几何形态来预测构造整体拉张量和滑脱层深度,面积守恒法可以利用同构造沉积地 层和已知的滑脱层位置来预测拉张构造整体的拉张量和不同阶段的拉张量变化。     

渤海湾盆地东濮凹陷古近系古湖盆氧化还原条件及其优质烃源岩的发育模式

通过分析东濮凹陷古近系沙河街组烃源岩样品的主微量元素含量,研究了东濮凹陷沙河街组优质烃源岩形成时的古氧化还原条件、古生产力水平及古水体的局限性,探讨了沙河街组沙三段优质烃源岩的发育模式。研究结果表明,东濮凹陷的北部沙三段优质烃源岩发育属于“深水窄盆水体分层沉积”模式。水体主要是咸水—超咸水,水体局限性较强,深度较深形成了稳定的盐度分层,从而造成底层水处于稳定的缺氧条件,有利于有机质的保存。根据主微量元素分析及古生产力的还原,沙三段沉积时水体表层富氧,发育大量有机质,生物死亡后有机质发生絮凝,在氧化还原界面吸附于铁锰氧化物的表面,沉降到底部,底部水体缺氧到还原的性质,适合保存有机质。东濮凹陷南部沙三段优质烃源岩发育属于“浅水广盆凹盆缺氧沉积”模式。湖泊水体为淡水,湖水局限性很弱,属于开阔水域,由于地表河流及洪水带来大量营养物质,表层水体古生产力较高,缺乏缺氧的保存条件,有机质生化阶段消耗较多,但是局部也可以发育弱还原水体,进而形成优 质烃源岩。     

北黄海盆地东部坳陷勘探突破对我国近海残留“黑色侏罗系”油气勘探的启示

最新的勘探和研究证实,北黄海盆地东部坳陷发育了中、上侏罗统2套有效烃源岩并以上侏罗统为主力烃源岩层,在其供烃范围内形成了上侏罗统-下白垩统"下生上储式"和中-上侏罗统"自生自储式"2类成藏组合,取得了我国东部海域以侏罗系为唯一源岩的含油气盆地勘探突破。为进一步探索我国近海盆地残留"黑色侏罗系"的资源潜力和勘探前景,本文采用地震-地质综合解释、烃源岩地球化学分析、盆地模拟等方法,综合分析了我国近海主要盆地残留"黑色侏罗系"的分布和地球化学特征。结果表明,我国近海残留侏罗系暗色泥岩烃源岩非均质性较强,多属"中等"级别,局部发育"中等-好"、"中等-差"级别烃源岩,侏罗系烃源岩大多存在早（J₃-K₁）、晚（E₂末-N₁）2期生、排烃高峰,生烃总量达1.4×10¹¹ t,资源前景乐观,预测可形成侏罗系"自生自储式"和侏罗系-白垩系（或新生界）"下生上储式"2类源储组合。     

涠西南凹陷流沙港组烃源岩生产力及发育模式

涠西南凹陷是中国近海北部湾盆地已证实的富烃凹陷,始新统流沙港组是该凹陷主要烃源岩层系.为深入认识涠西南凹陷流沙港组烃源岩的生产力和发育特征,采用有机地球化学与地球生物学相结合、定性分析与定量计算相结合的方法正演恢复了涠西南凹陷不同次洼流沙港组不同层段烃源岩的古生产力、有机质埋藏效率和有机碳埋藏生产力,进而建立了研究区流沙港组烃源岩形成的地球生物学模式.结果表明,涠西南凹陷流沙港组烃源岩的古生产力、有机质埋藏效率及有机碳埋藏生产力在横向不同次洼和纵向不同层段上均存在差异,横向上以B次洼最优,纵向上以流二段最高;涠西南凹陷流沙港组烃源岩发育超营养湖高埋藏效率高埋藏生产力、富营养湖中等埋藏效率中等埋藏生产力及富营养湖低埋藏效率低埋藏生产力3种代表性的地球生物学模式.     

珠江口盆地的沉积充填与珠江的形成演变

沉积物元素地球化学分析表明,南海北部地区沉积物渐新统与中新统明显不同,两者之间存在物源突变事件。这一沉积地质事件在时间上与南海扩张轴发生跳跃、滇西高原以及东喜马拉雅构造结的快速隆升等一系列地质构造事件十分吻合,是珠江以及珠江口盆地搬运—沉积—充填演化史上一次重大的转变。Ca/Si、CIA以及Al₂O₃等参数变化显示,珠江侵蚀区极有可能由渐新世近源硅酸盐为主的华南沿海地区拓展为中新世远达青藏高原东麓的云贵高原碳酸盐为主的地区,流域范围突然扩大。同时伴随沉积物供给增大,造成珠江口盆地从渐新世富砂为主的沉积堆积体系转变为中新世以来以泥为主的沉积堆积体系,显示出珠江的发育演化以及中新世以来的青藏高原隆升在南海北部的沉积充填演变中扮演了重要角色,对南海北部地区油气藏的形成影响深远。     

南堡凹陷东营组层序地层格架与沉积体系

通过对地震、岩心、钻、测井资料综合分析,将东营组划分为1个二级层序、3个三级层序。并根据初次湖泛面和最大湖泛面特征将每个层序进一步划分为低位域、湖侵域和高位域等三个体系域。层序格架和展布受凹陷结构和断裂活动影响,高柳断层以北地区东营组沉积厚度薄,且后期剥蚀严重。南部滩海地区的各层序完整,厚度相对稳定。在层序格架内分析了南堡凹陷东营组的沉积体系,东北部陡坡带以发育水下扇、扇三角洲为主,西北部和南部缓坡带发育三角洲、扇三角洲和辫状河三角洲。层序界面、准层序（组）叠加样式以及沉积体系空间展布均受到构造活动的控制,强构造活动期形成退积式叠加模式,而弱构造活动期对应进积式叠加模式。对层序发育和油气成藏条件分析认为层序1低位域的扇三角洲砂体和层序2中的浊积砂体为寻找岩性油气藏的有利部位。     

Early Cenozoic paleontological assemblages and provenance evolution of the Lishui Sag,East China Sea

The East China Sea Shelf Basin generated a series of back-arc basins with thick successions of marine- and terrestrial-facies sediments during Cenozoic. It is enriched with abundant oil and gas resources and is of great significance to the petroleum exploration undertakings. Therein, the Lishui Sag formed fan delta, fluvial delta and littoral-to-neritic facies sediments during Paleocene–Eocene, and the research on its sedimentary environment and sediment source was controversial. This study analyzed the paleontological combination characteristics, and conducted a source-to-sink comparative analysis to restore the sedimentary environment and provenance evolution of the Lishui Sag during Paleocene–Eocene based on the integration of detrital zircon U-Pb age spectra patterns with paleontological assemblages. The results indicated that Lishui Sag was dominated by littoral and neritic-facies environment during time corroborated by large abundance of foraminifera, calcareous nannofossils and dinoflagellates. Chronological analysis of detrital zircon U-Pb revealed that there were significant differences in sediment sources between the east and west area of the Lishui Sag. The western area was featured by deeper water depths in the Paleocene–Eocene, and the sediment was characterized by a single Yanshanian peak of zircon U-Pb age spectra, and mainly influenced from Yanshanian magmatic rocks of South China Coast and the surrounding paleo-uplifts. However, its eastern area partly showed Indosinian populations. In particular, the upper Eocene Wenzhou sediments were featured by increasingly plentiful Precambrian zircons in addition to the large Indosinian-Yanshanian peaks, indicating a possible impact from the Yushan Low Uplift to the east. Therefore, it is likely that the eastern Lishui Sag generated large river systems as well as deltas during time. Due to the Yuquan Movement, the Lishui Sag experienced uplifting and exhumation in the late stage of the late Eocene and was not deposited with sediments until Miocene. Featured by transitional-facies depositions of Paleocene–Eocene, the Lishui Sag thus beared significant potential for source rock and oil-gas reservoir accumulation.     

Controlling factors on the charging process of oil and gas in the eastern main sub-sag of the Baiyun Sag,Zhujiang River (Pearl River) Mouth Basin

The eastern main sub-sag (E-MSS) of the Baiyun Sag was the main zone for gas exploration in the deep-water area of the Zhujiang River (Pearl River) Mouth Basin at its early exploration stage, but the main goal of searching gas in this area was broken through by the successful exploration of the W3-2 and H34B volatile oil reservoirs, which provides a new insight for exploration of the Paleogene oil reservoirs in the E-MSS. Nevertheless, it is not clear on the distribution of “gas accumulated in the upper layer, oil accumulated in the lower layer” (Gas_upper-Oil_lower) under the high heat flow, different source-rock beds, multi-stages of oil and gas charge, and multi-fluid phases, and not yet a definite understanding of the genetic relationship and formation mechanism among volatile oil, light oil and condensate gas reservoirs, and the migration and sequential charge model of oil and gas. These puzzles directly lead to the lack of a clear direction for oil exploration and drilling zone in this area. In this work, the PVT fluid phase, the origin of crude oil and condensate, the secondary alteration of oil and gas reservoirs, the evolution sequence of oil and gas formation, the phase state of oil and gas migration, and the configuration of fault activity were analyzed, which established the migration and accumulation model of Gas_upper-Oil_lower co-controlled by source and heat, and fractionation controlled by facies in the E-MSS. Meanwhile, the fractionation evolution model among common black reservoirs, volatile reservoirs, condensate reservoirs and gas reservoirs is discussed, which proposed that the distribution pattern of Gas_upper-Oil_lower in the E-MSS is controlled by the generation attribute of oil and gas from source rocks, the difference of thermal evolution, and the fractionation controlled by phases after mixing the oil and gas. Overall, we suggest that residual oil reservoirs should be found in the lower strata of the discovered gas reservoirs in the oil-source fault and diapir-developed areas, while volatile oil reservoirs should be found in the deeper strata near the sag with no oil-source fault area.