阿布扎比石油系统卤化刺激研究

A. Noufal, H. Shebl
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As a passive margin during Paleozoic time, the Arabian plate accumulated a continentally influenced shallow marine sequence characterized by interbedded siltstones, sandstones, shales and carbonates sediments. The Late Ordovician-Early Silurian glaciation interrupted the Paleozoic deposition by lowering sea level in the Late Silurian and Late Carboniferous-Early Permian glaciation.\n Salt movement was started an extensional phase in Permo-Jurassic with the Neo-Tethys opening and basement faults reactivation. Followed by Cretaceous compression stress due to Afro-Arabian Plate movement. The third phase happened by Late Cretaceous with the closing of the Neo-Tethys. The salt was finally pierced to the surface by Mid Tertiary compression stress forces accompanied with Oman thrusting and Zagros folding. Since Miocene uplift, the salt movement extended until present day onwards. Previously, the pierced salt was considered stacked, but subsidence measurements indicating salt is still moving in some islands reaching about 2cm per year.\n This paper uses 3D seismic, core data and outcrops investigations to assess the geometry, kinematics, and the halokinetic phases that stimuluses the hydrocarbon exploration targets. The paper revisited the flowage phases of the salt in Abu Dhabi, investigated the accompanying fault geometries and relate this to the structural styles. The diapiric anticlines forming during salt movement phases forming domal structures with radial faults. Contradicting what is known, the Miocene-recent strata are tilted indicating the continuation of the salt movement. The Hormuz salt is characterized by a regionally consistent stratigraphy, formed of evaporites interbedded with clastic and carbonate sediments with dolomite intervals and vein intrusions of volcanic rocks.\n Interpreted faults were categorized into three families, Type I comprising domal radial faults, Type II representing faults triggered salt movements and Type III describing salt movements triggered faults. The first type is characterizing itself by its location relative to the crystal parts of the domes. The relatively low overburden pressure at the crest of the diapir and the original high dip angles of these fault planes favor salt intrusions near the diapir crest. Depending on the salt movement phases, the generated cycles of these faults, are characterized by different dips and areas of extension, while the other two categories can be differentiated as well. At the time of salt movement initiation, these faults were incipiently intruded by salt for relieving the intense internal overpressure in the salt body. These pressures are due to the compression forces associated with the salt movement, the buoyancy effects compensating the density difference between salt and overlying sediments and the tectonic compression forces. 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引用次数: 1

摘要

卤代烃强烈地刺激了阿布扎比的石油系统。在晚前寒武纪,阿拉伯板块和相邻板块的基底地体沿着非洲冈瓦纳大陆板块的东北边缘融合在一起。这一阶段之后是大陆裂谷和大陆内伸展。阿拉伯下寒武纪伸展体系在阿曼南部的Zagros地区和阿拉伯湾建立了裂陷盐盆地。这些地区的霍尔木兹盐中含有玄武岩和流纹岩,表明这一时期的构造伸展。扎格罗斯逆冲断层和迪巴转换断层确定了阿拉伯湾霍尔木兹杂岩的现今边界。阿拉伯板块作为古生代的被动边缘,形成了以粉砂岩、砂岩、页岩和碳酸盐沉积互层为特征的陆相浅海层序。晚奥陶世—早志留世冰期通过降低晚志留世和晚石炭世—早二叠世冰期的海平面,中断了古生代的沉积。随着新特提斯构造的张开和基底断裂的重新激活,二叠统—侏罗纪伸展期开始了盐的运动。其次是白垩纪由非洲-阿拉伯板块运动引起的压缩应力。第三阶段发生在晚白垩纪,随着新特提斯时期的结束。在阿曼逆冲和扎格罗斯褶皱的作用下,中第三纪挤压应力最终将盐层刺穿地表。中新世隆升以来,盐运动一直延续至今。以前,人们认为穿洞的盐是堆积在一起的,但沉降测量表明,一些岛屿上的盐仍在移动,每年移动约2厘米。本文利用三维地震、岩心数据和露头调查来评估刺激油气勘探目标的几何、运动学和盐动力学阶段。本文重新考察了阿布扎比盐的流动阶段,研究了伴随的断层几何形状,并将其与构造样式联系起来。盐运动期形成的底辟背斜形成带径向断裂的穹状构造。与已知的相反,中新世-新近地层是倾斜的,表明盐运动的继续。霍尔木兹盐具有区域一致的地层特征,由蒸发岩与碎屑和碳酸盐沉积物互层形成,白云岩间隔和火山岩脉状侵入。解释断裂可分为三大类,ⅰ型为穹状径向断裂,ⅱ型为断层引发盐运动,ⅲ型为盐运动引发断层。第一种类型的特点是其相对于圆顶的晶体部分的位置。底辟顶相对较低的覆盖层压力和原有的高倾角有利于底辟顶附近的盐侵入。根据不同的盐运动阶段,这些断层的生成旋回具有不同的倾角和伸展范围,而其他两类断层也可以区分开来。在盐运动开始时,这些断裂为缓解盐体内部强烈的超压而被盐侵入。这些压力是由于与盐运动相关的压缩力,浮力效应补偿盐和上覆沉积物之间的密度差以及构造压缩力。后者是允许盐沿断层面和层理面渗透的合理机制。盐的运动对含油气系统,特别是圈闭的影响,似乎盐的运动先于油气的运移,从而导致断层的封闭,反之亦然。
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Halokinesis Stimuluses on Petroleum System of Abu Dhabi
Halokinesis has strongly stimuluses the Abu Dhabi petroleum system. During the Late Precambrian, the basement terranes of the Arabian and adjoining plates were fused along the northeastern margin of the African Gondwanaland plate. This phase was followed by continental rifting and intra-continental extension. The Arabian Infracambrian extensional system established rifted salt basins in the Zagros region, South Oman and in the Arabian Gulf. The Hormuz salt in these areas contains basalt and rhyolite, suggesting tectonic extension at this time. The Zagros thrust fault and Dibba transform fault define the current limits of the Hormuz Complex of the Arabian Gulf. As a passive margin during Paleozoic time, the Arabian plate accumulated a continentally influenced shallow marine sequence characterized by interbedded siltstones, sandstones, shales and carbonates sediments. The Late Ordovician-Early Silurian glaciation interrupted the Paleozoic deposition by lowering sea level in the Late Silurian and Late Carboniferous-Early Permian glaciation. Salt movement was started an extensional phase in Permo-Jurassic with the Neo-Tethys opening and basement faults reactivation. Followed by Cretaceous compression stress due to Afro-Arabian Plate movement. The third phase happened by Late Cretaceous with the closing of the Neo-Tethys. The salt was finally pierced to the surface by Mid Tertiary compression stress forces accompanied with Oman thrusting and Zagros folding. Since Miocene uplift, the salt movement extended until present day onwards. Previously, the pierced salt was considered stacked, but subsidence measurements indicating salt is still moving in some islands reaching about 2cm per year. This paper uses 3D seismic, core data and outcrops investigations to assess the geometry, kinematics, and the halokinetic phases that stimuluses the hydrocarbon exploration targets. The paper revisited the flowage phases of the salt in Abu Dhabi, investigated the accompanying fault geometries and relate this to the structural styles. The diapiric anticlines forming during salt movement phases forming domal structures with radial faults. Contradicting what is known, the Miocene-recent strata are tilted indicating the continuation of the salt movement. The Hormuz salt is characterized by a regionally consistent stratigraphy, formed of evaporites interbedded with clastic and carbonate sediments with dolomite intervals and vein intrusions of volcanic rocks. Interpreted faults were categorized into three families, Type I comprising domal radial faults, Type II representing faults triggered salt movements and Type III describing salt movements triggered faults. The first type is characterizing itself by its location relative to the crystal parts of the domes. The relatively low overburden pressure at the crest of the diapir and the original high dip angles of these fault planes favor salt intrusions near the diapir crest. Depending on the salt movement phases, the generated cycles of these faults, are characterized by different dips and areas of extension, while the other two categories can be differentiated as well. At the time of salt movement initiation, these faults were incipiently intruded by salt for relieving the intense internal overpressure in the salt body. These pressures are due to the compression forces associated with the salt movement, the buoyancy effects compensating the density difference between salt and overlying sediments and the tectonic compression forces. The latter is the reasonable mechanisms that allow salt penetration along fault planes and bedding planes. This paper provides evidences that salt movements impact the petroleum system, especially traps, as if the salt movement preceding the hydrocarbon migration, this leads to faults sealing and the reverse is also applied.
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