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1.
为明确鄂尔多斯盆地中南部上古生界层序特点与岩相古地理演化规律,利用周缘野外露头和盆地钻井测井相特征,分析层序界面、体系域界面的岩性、古构造及海侵方向变化特征,总结层序发育特点与岩相古地理演化规律。结果表明: 不同风化序列的区域性不整合面及海侵方向转换面为二级层序界面,区域性海退面、下切冲刷面及陆上暴露面为三级层序界面; 潮间带砂坪及近岸相海侵含砾砂岩顶为海侵面,最大海侵面发育灰岩、泥页岩及煤层,是海侵体系域与高位体系域分界面; 上古生界包括二级层序2个: MSQ1、MSQ2,三级层序6个: SQ1、SQ2、SQ3、SQ4、SQ5、SQ6,其中SQ1—SQ2发育水进体系域与高位体系域,不发育低位体系域,SQ1为潟湖—障壁海岸沉积体系,SQ2为泥炭坪—泥坪相潮坪沉积;SQ3—SQ6发育完整的低位—海侵—高位体系域,SQ3发育区域性海退进积海陆过渡相三角洲沉积,SQ4早期为低位体系域下切冲蚀砂体,晚期沉积古环境由温暖湿润还原环境演变为炎热干燥的氧化环境,SQ5—SQ6早中期为氧化环境三角洲沉积,SQ6晚期为高位体系域具海侵夹层的潮坪相沉积。研究为鄂尔多斯盆地及其他盆地层序与岩相古地理演化提供理论依据。 相似文献
2.
根据山东惠民盆地中央隆起带古近系沙河街组第三段层序地层学研究,根据层序中湖平面变化特点和相应的沉积物特征,提出了陆相湖盆中层序内体系域的四分法,一个完整的层序由低位、湖侵、高位和下降四个体系域组成,并且层序界面位于湖平面最大下降的位置,介于下降域和低位域之间。层序地层中存在四个关键性界面:首泛面、最大湖泛面、始降面和最大下降面,其中首泛面对应于湖水由相对稳定到快速上升时的初始湖泛面,为低位域与湖侵域间的分界面;最大湖泛面对应于湖水快速上涨至最大限度时的湖泛面,为湖侵域与高位域间的分界面,在界面附近多形成特征的CS段;始降面对应于湖平面开始快速下降时的沉积界面,为高位域与下降域的分界面;最大下降面也是层序界面,为湖盆水体快速下降或湖盆岸线快速退到最低点时的沉积界面。结合研究区的岩芯、录井、测井、地震等资料综合分析,本文总结了四个关键面的识别标志。中央隆起带沙三段沉积共划分出六个体系域,分属三个层序。本文以层序II沉积为例,阐述了不同体系域的沉积体系特征,低位期湖盆水域面积小,河流-三角洲沉积体系发育,河流流经距离长,边缘地区形成似下切谷沉积;湖侵期发育小规模的退积式三角洲沉积,砂体较不发育;高位期湖盆水域面积大,砂体以深水浊积砂体为特征;下降期多发育进积式砂体,砂体发育。因此,位于层序界面之下的下降域和之上的低位域是湖盆砂体有利发育期,湖侵域和高位域是生油岩主要形成时期。 相似文献
3.
以层序地层学理论为指导,通过对岩石地层、测井地层、地震地层等资料的综合分析,将Llanos盆地中部始—中新统Carbonera组划分为4个三级层序。4个层序均由海侵体系域和高位体系域组成,缺失低位体系域。海侵体系域发育内陆棚~前三角洲泥质沉积,高位体系域以发育三角洲前缘砂质沉积为主,整体上显示为四套从海进到海退的沉积旋回。构造运动和海平面升降是控制Llanos盆地中部Carbonera组层序形成与发育的主要因素。层序演化及石油地质条件分析表明,高位体系域中发育的三角洲前缘水下分流河道,是寻找优质储层的有利目标。 相似文献
4.
根据测井、岩屑录井及地震资料,尼日尔三角洲Stubb Creek油田阿格巴达组可划分为SQl、SQ2、SQ3 3个层序.每个层序均由低位体系域、海侵体系域和高位体系域组成,符合Vail经典的层序地层学模式.各层序低位体系域底部在地震剖面上表现为一系列的削截面,高位体系域由下超面组成.层序界面还表现为沉积相的突变面.最大海泛面位于自然伽玛最大值处.低位体系域砂体在研究区北部最发育,向南部逐渐减薄,这与研究区的物源位于北部有关.研究区沉积体系包括下切谷充填、浅海陆棚和三角洲沉积体系.下切谷沉积体系分布在各层序低位体系域,浅海陆棚沉积体系分布在海侵体系域和高位体系域,而三角洲沉积体系仅分布在高位体系域. 相似文献
5.
近些年来,塔里木盆地塔河地区石炭系卡拉沙依组碎屑岩的油气勘探取得了丰硕成果。依据全球海平面变化,结合钻井和地震资料,本文划分了塔河地区石炭系卡拉沙依组层序,并提出其层序格架内的三种体系域沉积模式。塔河地区石炭系卡拉沙依组碎屑岩地层处于一个二级层序之内,其内部砂泥岩段被划分为5个三级层序。本文总结了每个层序界面、层序的内部特征及层序发育的控制因素,提出了塔河地区石炭系卡拉沙依组三级层序内的低位、海侵和高位3种体系域沉积模式,并分析了其内部沉积特征。塔河地区石炭系卡拉沙依组碎屑岩地层沉积物源为塔北剥蚀区,主要发育辫状河三角洲-陆棚沉积体系,其中上泥岩段整体主要发育浅海陆棚沉积,砂泥岩段(SQC1-2k^(5)—SQC1-2k^(1))海侵体系域主要发育退积型前三角洲,高位体系域主要发育进积型辫状河三角洲平原-三角洲前缘-前三角洲;低位体系域发育期主要作用于前一个三级层序的高位体系域,为三级层序界面形成期。构造运动、海平面升降、物源供给及古气候是塔河地区石炭系卡拉沙依组三级层序及其内部体系域发育的主要控制因素。 相似文献
6.
南海北部陆坡神狐海域峡谷作为我国水合物首次试采区,其沉积层序特征控制和影响着富含水合物沉积体的展布。海域峡谷区沉积作用复杂,影响因素较多,对比难度较大一直是全球深海沉积研究的难题之一。研究采用井震综合分析的方法识别出层序界面,并结合峡谷侵蚀—充填过程,刻画出不同级次的层序界面在空间上的展布。研究划分出6个四级层序,但是各层序内部同相轴发育特征不同:层序Ⅲ和层序Ⅳ的底界可见明显的下切谷和峡谷定向迁移现象,层序Ⅴ和层序Ⅵ层序可见明显的同相轴错断现象。依据层序结构样式存在的差异,将研究区层序类型分成物源驱动型层序和沉降驱动型层序。然后统计层序Ⅰ—Ⅳ内部的沉积参数,根据陆坡滨岸线的演化过程将物源驱动型层序和沉降驱动型层序进行体系域划分。最后将两种类型的层序进行解剖并提出对应的演化模式:物源驱动型层序可以再划分成3个体系域,即低位域、海侵域和高位域,整体物源供给较充足,沟谷侵蚀现象明显,陆坡滨岸线多呈上超结构;沉降驱动型层序划分成4个体系域,即低位域、海侵域、高位域和海退域,其中海退体系域为最大海泛面和峡谷侵蚀面间的规则前积体,层序发育过程伴随断裂沉降,陆坡滨岸线多呈S型结构。 相似文献
7.
以层序地层学及沉积学理论为指导,综合运用测井、录井以及地震资料,将尼日尔Termit盆地上白垩统Madama组划分为一个三级层序(MS),并进一步识别出低位体系域、海侵体系域以及高位体系域。在等时层序地层格架内,识别出前积反射地震相、河道充填反射地震相、平行-亚平行反射地震相以及杂乱反射地震相等四种类型,并识别出辫状河三角洲的沉积相类型。认为层序MS的低位体系域主要发育辫状河三角洲前缘亚相,高位体系域则主要发育辫状河三角洲平原亚相。Madama组整体表现为一个海退的沉积演化过程。 相似文献
8.
为了深入认识川西坳陷中段须四段层序地层格架内沉积特征,综合利用野外露头、地震、岩心、测/录井、分析测试等资料对其进行了系统分析。结果表明须四段为一个三级层序,根据层序界面特征划分出低位体系域、湖侵体系域和高位体系域,并建立了等时层序地层格架。依据沉积相标志识别出冲积扇、辫状河、辫状河三角洲和湖泊4种相类型,明确了层序地层格架内沉积相平面展布及纵向演化特征:平面上,短轴物源自龙门山山前依次发育冲积扇、辫状河、辫状河三角洲和湖泊相,长轴物源主要发育辫状河三角洲前缘沉积,长短轴物源在合兴场-德阳-马井-新繁镇一带地区交汇;纵向上,低位体系域和高位体系域时期以辫状河三角洲前缘沉积为主,水下分支河道砂体纵向叠置、横向连片、分布广泛,湖侵体系域时期以滨浅湖沉积为主。建立了层序-沉积充填模式,指出低位体系域和高位体系域时期的长轴物源和长短轴物源交汇区辫状河三角洲前缘水下分支河道砂体是研究区优质储层发育区。 相似文献
9.
利用地震沉积学、层序地层学的相关理论和方法,结合钻测井数据、地震反射结构特征、均方根振幅属性和滨线迁移轨迹特征等资料,对珠江口盆地白云凹陷北坡21 Ma强制海退体系域的识别特征、演化模式和油气意义进行了探讨,指出该体系域在平行物源方向具有高角度斜交型前积反射,其前端靠近盆地中心发育具丘状反射的盆底扇,滨线迁移轨迹呈向盆地方向逐级下降的趋势。结果表明:强制海退体系域在垂直物源方向发育"U"型的下切谷,内部为平行的地震反射充填结构;测井曲线为漏斗形和箱型的组合特征,表现为多个四级相对海平面变化控制的准层序组,且每个准层序组都具有向上水体变浅和顶部突然变深的特征;强制海退体系域之下为前期层序高位体系域的前三角洲或陆架泥岩,其上沉积了海侵体系域和高位体系域的半深海暗色泥岩,同时受陆架坡折带地层尖灭和断裂沟通深部油源的控制,可形成有利的生、储、盖组合,是寻找岩性油气藏的有利场所。 相似文献
10.
运用露头、钻井岩心层序地层学的有关理论方法,对蹬槽剖面的晚古生代地层进行了详细的沉积学和层序地层学研究,共识别出8个三级层序界面,把本研究区域晚古生代地层划分为7个三级层序。S1大致相当于本溪组;S2大致相当于太原组;S3大致相当于山西组;S4和S5分别对应下石盒子组的上下部分;S6对应上石盒子组;S7对应石千峰组。在这些层序中,低位体系域往往以发育三角洲平原分流河道相砂砾岩、或残积相风化壳、或滨湖相中细砂岩为特征,而水进体系域多障壁岛-潟湖相泥岩和粉砂岩、三角洲前缘相砂泥层以及浅湖相细砂岩为主,高位体系域则主要为浅海相碳酸盐岩、前三角洲相泥岩及富泥质的浅湖相沉积序列。层序S1~层序S2物源不丰富,聚煤作用主要发生在海侵初期或海退时期;层序S3~层序S6物源相对丰富,聚煤作用主要出现在最大海泛附近。 相似文献
11.
The passive margin Texas Gulf of Mexico Coastal Plain consists of coalescing late Pleistocene to Holocene alluvial–deltaic plains constructed by a series of medium to large fluvial systems. Alluvial–deltaic plains consist of the Pleistocene Beaumont Formation, and post-Beaumont coastal plain incised valleys. A variety of mapping, outcrop, core, and geochronological data from the extrabasinal Colorado River and the basin-fringe Trinity River show that Beaumont and post-Beaumont strata consist of a series of coastal plain incised valley fills that represent 100 kyr climatic and glacio-eustatic cycles. Valley fills contain a complex alluvial architecture. Falling stage to lowstand systems tracts consist of multiple laterally amalgamated sandy channelbelts that reflect deposition within a valley that was incised below highstand alluvial plains, and extended across a subaerially-exposed shelf. The lower boundary to falling stage and lowstand units comprises a composite valley fill unconformity that is time-transgressive in both cross- and down-valley directions. Coastal plain incised valleys began to fill with transgression and highstand, and landward translation of the shoreline: paleosols that define the top of falling stage and lowstand channelbelts were progressively onlapped and buried by heterolithic sandy channelbelt, sandy and silty crevasse channel and splay, and muddy floodbasin strata. Transgressive to highstand facies-scale architecture reflects changes through time in dominant styles of avulsion, and follows a predictable succession through different stages of valley filling. Complete valley filling promoted avulsion and the large-scale relocation of valley axes before the next sea-level fall, such that successive 100 kyr valley fills show a distributary pattern. Basic elements within coastal plain valleys can be correlated with the record offshore, where cross-shelf valleys have been described from seismic data. Falling stage to lowstand channelbelts within coastal plain valleys were feeder systems for shelf-phase and shelf-margin deltas, respectively, and demonstrate that falling stage fluvial deposits are important valley fill components. Signatures of both upstream climate change vs. downstream sea-level controls are therefore interpreted to be present within incised valley fills. Signatures of climate change consist of the downstream continuity of major stratigraphic units and component facies, which extends from the mixed bedrock–alluvial valley of the eroding continental interior to the distal reaches, wherever that may be at the time. This continuity suggests the development of stratigraphic units and facies is strongly coupled to upstream controls on sediment supply and climate conditions within hinterland source regions. Signatures of sea-level change are critical as well: sea-level fall below the elevation of highstand depositional shoreline breaks results in channel incision and extension across the newly emergent shelf, which in turn results in partitioning of the 100 kyr coastal plain valleys. Moreover, deposits and key surfaces can be traced from continental interiors to the coastal plain, but there are downstream changes in geometric relations that correspond to the transition between the mixed bedrock–alluvial valley and the coastal plain incised valley. Channel incision and extension during sea-level fall and lowstand, with channel shortening and delta backstepping during transgression, controls the architecture of coastal plain and cross-shelf incised valley fills. 相似文献
12.
以贵州紫晚二叠世碳酸盐台地边缘礁为例,运用高频层序地层学原理和方法,精细地划分了紫云礁层序的各级单元,并对其内部沉积构成进行了详细研究,探讨海平面和变化对礁体生长的控制,研究结果表明,晚二叠世紫云礁 合体为发育在台地边缘坡折带的一个三级层序,由13个准层序组成,并可识别出低位、海侵、高位3个体系域,低位期的下切谷 边缘坡折带碳酸盐台地的暴露、海侵期和高位期礁的3种生长方式的增生及每种生长方式的特定 相似文献
13.
The lower part of the Cretaceous Sego Sandstone Member of the Mancos Shale in east‐central Utah contains three 10‐ to 20‐m thick layers of tide‐deposited sandstone arranged in a forward‐ and then backward‐stepping stacking pattern. Each layer of tidal sandstone formed during an episode of shoreline regression and transgression, and offshore wave‐influenced marine deposits separating these layers formed after subsequent shoreline transgression and marine ravinement. Detailed facies architecture studies of these deposits suggest sandstone layers formed on broad tide‐influenced river deltas during a time of fluctuating relative sea‐level. Shale‐dominated offshore marine deposits gradually shoal and become more sandstone‐rich upward to the base of a tidal sandstone layer. The tidal sandstones have sharp erosional bases that formed as falling relative sea‐level allowed tides to scour offshore marine deposits. The tidal sandstones were deposited as ebb migrating tidal bars aggraded on delta fronts. Most delta top deposits were stripped during transgression. Where the distal edge of a deltaic sandstone is exposed, a sharp‐based stack of tidal bar deposits successively fines upward recording a landward shift in deposition after maximum lowstand. Where more proximal parts of a deltaic‐sandstone are exposed, a sharp‐based upward‐coarsening succession of late highstand tidal bar deposits is locally cut by fluvial valleys, or tide‐eroded estuaries, formed during relative sea‐level lowstand or early stages of a subsequent transgression. Estuary fills are highly variable, reflecting local depositional processes and variable rates of sediment supply along the coastline. Lateral juxtaposition of regressive deltaic deposits and incised transgressive estuarine fills produced marked facies changes in sandstone layers along strike. Estuarine fills cut into the forward‐stepped deltaic sandstone tend to be more deeply incised and richer in sandstone than those cut into the backward‐stepped deltaic sandstone. Tidal currents strongly influenced deposition during both forced regression and subsequent transgression of shorelines. This contrasts with sandstones in similar basinal settings elsewhere, which have been interpreted as tidally influenced only in transgressive parts of depositional successions. 相似文献
14.
High resolution seismic lines from the inner and mid-shelf of the Durban Bight reveal an unprecedented view of the seismic stratigraphy of the central KwaZulu-Natal uppermost continental margin. Seven units are recognised from the shelf on the basis of their stratal architecture and bounding unconformities. These comprise four incompletely preserved sequences consisting of deposits of the highstand systems tract (Unit B), falling stage systems tracts (Unit C), the transgressive systems tract (Units A, D and G) and lowstand systems tracts (early fill of the incised valleys and strike diachronous prograding reflectors of Unit A). Seismic facies recognised as incised valley fills correspond to the lowstand and transgressive systems tracts. When integrated with published accounts of onshore and offshore lithostratigraphy and local sea level curves, we recognise an Early Santonian transgression (Unit A to Unit B), superimposed by uplift-induced pulses of forced regression. A Late Campanian relative sea level fall (Unit C) followed. Sediments of the Tertiary period are not evident on the Durban Bight shelf except for isolated incised valley fills of Unit D lying within incised valleys of Late Pliocene age. Overlying these are two stages of Pleistocene shoreline deposits of indeterminate age. Erosion concurrent with relative sea level fall towards the last glacial maximum shoreline carved a third set of incised valleys within which sediments of the Late Pleistocene/Holocene have infilled. 相似文献
15.
东河砂岩是沉积于早海西期角度不整合面之上的第一套旋回性地层单元,它是由最底部的低水位体系域(LST)、海侵体系域(TST)及高水位体系域组成的Ⅰ类标准沉积层序,相当于三级海平面旋回的沉积地层。LST以缺失其早期的盆底扇、斜坡楔状体等为特征,仅发育其晚期的陆上河流充填沉积;TST中不发育凝缩层段,副层序在垂向上以弱退积至加积方式堆叠。一个完整的海平面相对升降旋回导致区内不同时期、不同地区的沉积体系及沉积特征不同。 相似文献
17.
泥盆纪时,黔南地区为一相对稳定的台地,早泥盆世晚期,海水开始漫漫其上.初始发育陆源碎屑沉积体系,中泥盆世发育陆源碎屑~碳酸盐混合体系.空间配置有下列几种类型:滨岸障壁~泻湖~河流体系,碳酸盐缓坡~滨岸障壁~泻湖体系,镶边型碳酸盐台地~泻湖三角洲(潮坪)体系,碳酸盐缓坡~三角洲体系。基底断裂限定了台地和台间沟的延限范围和演化进程,这两种不同沉积背景的沉积演化旋回可能主要受海平面变化控制。 相似文献
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以库车前陆盆地为例,对陆相前陆盆地的形成、沉积充填与层序地层结构、不整合面与层序界面、层序地层组成与其模式、生储盖组合与岩性地层圈闭等关键问题进行了探讨。认为前陆层序是盆缘构造运动的响应,由低位(冲积)体系域、湖侵体系域、高位体系域组成。前陆盆地层序界面表现为构造或沉积不整合面,代表了一次构造幕的发生,其层序地层样式是盆缘造山带构造楔推进作用的结果,是盆地演化的不同阶段的响应,反映了构造运动由强到弱的间歇变化。前陆层序界面代表了沉积结构的大转换,之下为构造稳定阶段的湖相泥岩或膏泥岩,之上为代表构造运动的冲积扇—扇三角洲相的巨厚磨拉石沉积充填。在构造活动期和静止期,盆地不同位置形成不同的沉积充填和地层结构特点。构造活动期以低位(冲积)体系域为主,在毗邻造山带侧以巨厚的冲积扇-扇三角洲-辫状河三角洲相等冲积沉积物为主;构造静止期以湖侵体系域为主,为广泛的河流-湖泊相沉积。沉积厚度从靠近冲断带侧向盆地内逐渐变小。陆相前陆盆地的生储盖组合配置好,储集体广泛分布于低位、湖侵和高位体系域中,以辫状河三角洲和滨湖相为主。其岩性地层圈闭主要分布在前缘斜坡带上,包括沿古隆起边缘的地层超覆不整合圈闭和地层削蚀不整合圈闭,将会成为今后油气勘探的新领域。 相似文献
19.
以层序地层学理论为指导,在井震联合标定的基础上,综合运用地震、测井、钻井、岩芯及野外露头资料,建立了塔北隆起哈拉哈塘地区白垩系卡普沙良群层序地层格架.将卡普沙良群划分为5个三级层序,并在层序格架内进行了沉积相识别及沉积体系研究,识别出了河流、三角洲及湖泊等沉积体系.结合前陆盆地构造演化阶段的分析,认识了沉积体系展布规律.指出油气勘探应围绕SQ1、SQ2、SQ5层序低位及高位体系域的储集砂体开展,在平面上研究区中部三角洲前缘相带为有利区带. 相似文献
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长江水下三角洲层序地层学研究有助于全面了解长江三角洲地层特征和沉积环境演化模式。通过对长江水下三角洲下切河谷区YD0901和YD0903孔岩心的详细沉积物粒度、特征元素比值(Cl/Ti和Zr/Rb)、沉积相对比分析,恢复了冰后期以来长江水下三角洲层序地层格架。研究区冰后期以来自下而上依次出现河流相、潮汐河流相、河口湾相、浅海相和三角洲相的沉积相序。末次冰期海平面下降,古长江形成下切河谷,古河间地发育硬黏土层,构成五级Ⅰ型层序界面。之后海平面回升,分别于15 cal ka BP和8.0 cal ka BP形成最大海退和最大海侵界面,水下三角洲区域最大海侵发生时间略滞后于平原区,约为7.5 cal ka BP。据此3个层序界面将冰后期地层划分为低位体系域、海侵体系域和高位体系域。钻孔岩心记录揭示了14.8 cal ka BP海侵到达研究区;14.8~13 cal ka BP期间,受MWP-1A冰融水事件影响海平面快速上升,海岸线向陆推进速率可达71.9,km/ka;海退期间各钻孔沉积速率较低,直至2 cal ka BP开始,沉积速率明显增加。 相似文献
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