鄂尔多斯盆地北部奥陶系碳酸盐岩层序地层…

碳酸盐岩的物源性质，形成背景，沉积机理和扩散方式都与碎屑岩有很大的差异，对于碳酸盐岩层序层地层，需要从成因上，从台地的性质与演化，海水的进退，台地淹没与暴露等方面进行研究，在总结露头层序地层工作方法的基础上，阐述了密集段，首次洪泛面和层序边界的识别标志，建立了高分辨率层序地层格架，鄂尔多斯盆地早奥陶世三次坎组沉积时，为碳酸盐岩－碎屑岩混合缓坡背景，桌子山组及克里摩里组沉积时为镶边陆架与末端陡倾缓坡     

影响沉积盆地相对海平面变化的多重因素和旋回层序响应

沉积盆地内相对海平面变化及沉积层序形成不仅受全球海平面变化旋回控制，而且沉积盆地所处的构造背景和相关因素，如：沉积物供给、盆底沉降和自然地理条件也对沉积层序及其内部组成——体系域具有极大的影响。对应于海平面变化发育的容纳空间旋回层序，沉积供给也可以形成特征的、可以鉴别的供给旋回层序。具有过渡性界线的三级或高频旋回层序受相对海平面变化和沉积供给双重因素控制。不同构造背景沉积盆地边缘发育不同的盆底沉降速率，相对海平面变化响应于盆缘沉降具有明显的构造－海平面分带，岸线在构造－海平面带中的地理位置决定了层序界面和层序堆叠样式，也同样影响着低位体系域的构成。深水盆地环境古地形特点及沉积物供给制约着深水沉积序列。构造运动显著地影响着沉积层序发育。碳酸盐缓坡和平顶镶边陆架的层序格架及体系域发育受其坡度、盆地深度及下降幅度的因素的作用。台地边缘和大陆边缘盆地浊积岩层序的发育和体系域组成受控于差异的沉积物源（平顶碳酸盐台地、镶边台地和陆源碎屑岩陆架）、古地理及构造活动性     

辽东半岛南部早古生代馒头组—冶里组沉积盆地演化

辽东半岛南部早古生代地层发育,其中馒头组－冶里组的沉积过程,具有完整的陆源碎屑岩－碳酸盐岩堆积特点。从层序划分、沉积环境演化、古气候变迁等方面分析,馒头组－冶里组反映了一个完整的碳酸盐岩台地的发展过程,可划分出准备阶段（形成碎屑岩垫板）、生长－发育阶段（形成碳酸盐岩缓坡）及衰亡阶段（发育白云岩盖层）。     

鄂尔多斯盆地南缘早古生代碳酸盐岩高频沉积旋回分析

鄂尔多斯盆地南缘早古生代碳酸盐岩台地的演化可分低能和高级缓坡、具局限性内陆架盆地的镶边陆架、虎蒸发性内陆架盆地的镶边陆架及断边缘４个阶段，在不同的演化 ，高频沉回旋类型具有明显差异，说明沉积背景控制了碳酸盐岩高频沉积旋回的复杂性、多样性、根据对和线个演经阶段高频旋回的分级栩比及周期计算表明，其驱动机制应与米兰科维奇的天文轨道有关。     

贵州省贵阳地区的三叠纪地层格架

经过野外填图和追索不整合面,在贵阳地区的三叠纪碳酸盐岩台地—盆地过渡带上识别出4个不整合界限地层单位(或“层序”),它们与哈克等人(1988)的三叠纪全球海面变化旋回表基本上可以对比。根据岩相和地层结构分析,进一步细分出:海侵的碳酸盐岩缓坡,高水位的镶边碳酸盐岩台地,低水位的碳酸盐岩斜坡和盆地碎屑岩—碳酸盐岩混合等四类沉积体系。有证据表明,海侵面是盆地地层序列内的重要沉积间断面,因此提议最好以陆上暴露带不整合—海侵面,作为不整合界限地层单位(“层序”)的界面。     

塔里木盆地东北缘库鲁克塔格地区寒武纪-奥陶纪沉积特征及演化

库鲁克塔格地区保存了相对完整的寒武纪-奥陶纪沉积地层,其沉积特征及演化规律的研究,对塔东地区寒武系-奥陶系油气勘探具有重要意义。通过库鲁克塔格地区详细的野外地质调查,结合前人相关研究成果,对该区寒武系-奥陶系沉积体系、沉积模式及演化规律的研究表明,寒武纪时期,库鲁克塔格地区经历了一次大的海侵-海退旋回,南、北两区沉积具有相似性。寒武纪早期的快速海侵导致南、北两区均发育陆棚相-深水盆地相沉积;寒武纪晚期,在逐渐海退的背景下,南、北两区开始出现沉积分异。奥陶纪,经历了新一轮大的海侵-海退旋回,南北两区沉积差异显著。北区从早奥陶世到晚奥陶世,发育台地边缘斜坡相-广海陆棚相-缓斜坡相-台地边缘礁滩相-开阔台地相相序,构成整体向上变浅的碳酸盐岩沉积层序;而南区发育深水盆地相-陆棚斜坡相-浊流盆地相-碎屑陆棚相相序,形成一套巨厚的深水复理石建造。库鲁克塔格地区寒武纪时期发育缓坡型碳酸盐岩台地,因台地不断向南构筑以及断裂活动,导致奥陶纪晚期台地边缘快速变陡,并在经历斜坡相快速堆积填平补齐之后,重新演变为缓坡型碳酸盐岩台地。晚奥陶世,由于周缘构造活动影响,却尔却克山-雅尔当山一带下沉,逐渐向远端变陡缓坡型碳酸盐岩台地演化。     

中东地区阿普特阶Shuaiba组碳酸盐岩沉积体系特征及模式探究

中东地区主力产油层系Shuaiba组的勘探及研究逐渐以地层岩性圈闭为主,笔者通过总结Bab盆地阿普特阶Shuaiba组沉积相类型,多油田地层格架及空间展布特征的对比,为系统恢复Shuaiba组沉积演化过程及模式提供地质依据。研究表明,阿普特阶Shuaiba组共发育开阔台地、台地边缘、台缘斜坡及盆地相4种沉积相单元和6种亚相类型,各相带单元受控于四个三级层序且沿Bab盆地周缘呈带状展布。开阔台地一侧,主要沉积了第二个三级层序对应的Lower Shuaiba地层;台地边缘往Bab台内盆地区域,则以第三和第四个三级层序对应的Upper Shuaiba地层为主。Shuaiba组生物礁、滩建造集中发育在第二个三级层序的高位域阶段,滩间海、缓坡及盆地相受控于海进和低位体系域。阿普特阶Shuaiba台地边缘生物建隆、台内浅滩在空间上相互叠置并成带展布,符合弱镶边型缓坡台地沉积模式,该类型台地具备深水陆棚性质的非常宽缓的斜坡,且缓坡往盆地一侧发育一个镶边台地边缘。     

碳酸盐岩台地类型、特征及主控因素

在总结前人工作的基础上,结合作者对塔里木盆地和四川盆地碳酸盐岩的研究,根据地理位置、坡度、封闭性和镶边性把碳酸盐岩台地分为以下类型:缓坡开放型无镶边台地、缓坡封闭型无镶边台地、陡坡开放型无镶边台地、陡坡封闭型无镶边台地、缓坡开放型有镶边台地、缓坡封闭型有镶边台地、陡坡开放型有镶边台地、陡坡封闭型有镶边台地、礁滩型孤立台地、岩隆型孤立台地。总结了不同类型碳酸盐岩台地沉积特征并建立了沉积模式,用以指导当前碳酸盐岩的油气勘探。最后,探讨了不同类型台地形成和发育的主控因素,认为构造运动所形成的古地形(貌)和水体能量控制台地和沉积物的类型,海平面的升降控制台地类型及沉积物的变化。     

塔里木盆地寒武-奥陶系碳酸盐岩台地样式及其沉积响应特征

从寒武纪到奥陶纪,塔里木盆地经历了早、中寒武世缓坡型碳酸盐岩台地,晚寒武世—早中奥陶世弱镶边斜坡型碳酸盐岩台地,晚奥陶世早期孤立型碳酸盐岩台地和晚奥陶世中晚期淹没型碳酸盐岩台地四种不同台地结构型式的演变。不同类型的碳酸盐岩台地在其剖面结构、台地边缘特征、沉积相构成等方面有着显著差异,它控制了不同区域沉积相类型和特征,并决定了烃源岩、储集岩和区域盖层的发育条件和展布规律。通过地震、钻井层序地层分析,总结出了不同类型的碳酸盐岩台地结构的层序—沉积相模式。在碳酸盐岩台地演变过程中,塔里木盆地发育二期坡折带:寒武纪—早中奥陶世形成第一期坡折带,沿着库南1井—满参1井—塔东2井一线分布,呈向西凸伸的弧形带;晚奥陶世发育第二期坡折带,由库南1井—满参1井—塔中1井—塘参1井延伸,呈向东凸伸的弧形带。坡折带的迁移变化,反映着台地样式的转变。     

华北寒武系层序地层格架及碳酸盐台地演化

华北寒武系包括两大套岩系，即辛集组至徐庄组以碎屑岩与碳酸盐岩交互沉积为特征的岩系，代表碳酸盐台地的发展阶段；张夏组至上寒武统的碳酸盐岩系，代表台地的成熟阶段，其中张夏组代表平顶型台地发育阶段，晚寒武世地层形成缓坡型台地的发育阶段。在岩性、岩相、相序研究的基础上，在寒武纪地层中识别出８个三级层序，它们在碳酸盐台地不同的发育阶段，具有不同的相序特征，以及由不同的相序组构代表的、不同的地层堆积作用特点。     

Study on Carbonate Sequence Stratigraphy of Ordovician in Northern Ordos Basin

INTRODUCTIONSeqUenCestratigraphyisderivedfromseismicstratigl'aphyanditSconCeptShaveholargelyappliedtosill~ticsetting(e.g.passivemargin,I'alnP,groWth--faulting,activemarginandnonmarinesettings).InrecentyearS,thestudyofseqUenCestratigraphyhasdlawnagreatattentionfromgeologistSovertheworld.Carbonaterocksareimportantcomponentsofthesedimentaryrecord,beingmajorresouras(e.g.salt,potash,~),containinghydrOCarbon"serves,andyieldingawealthofpaleoclilnaticandpaleo--enviromnentalinfonnation~r,1991…     

湘西北上震旦统碳酸盐层序地层

碳酸盐层序地层应考虑碳酸盐＂加工厂＂、气候条件、构造背景、沉降速率、与陆地连接情况和底质类型等多种因素。碳酸盐层序地层模式在大多数情况下有别于Ｖａｉｌ的碎屑岩层序地层模式，并且气候条件是一个值得多加考虑的因素。通过不同相区碳酸盐层序地层的划分，笔者建立了研究区上震旦统碳酸盐层序地层模式，即陵山沱期为缓坡背景碳酸盐层序地层模式，灯影期为碳酸盐台地（初始）背景层序地层模式。在高水位体系域中识别出早期高水位体系域和晚期高水位体系域。已识别出浅潮下和环潮坪两种不同类型的副层序旋回。通过层序地层分析，笔者认为陡山沱底部的白云岩属于低水位楔。     

Facies partitioning and sequence stratigraphy of cool-water, mixed carbonate-siliciclastic sediments (Upper Miocene Guadalquivir Domain, southern Spain)

During the late Miocene, the Guadalquivir Basin and its satellite basin, the Ronda Basin, were under Atlantic cool-water influence. The aim of our study is to develop a sequence stratigraphic subdivision of the Ronda Basin fill and to provide models for the cool-water carbonates. The Upper Miocene of the Ronda Basin can be divided into three depositional sequences. Sequence 1 is early Tortonian, Sequence 2 late Tortonian to earliest Messinian, and Sequence 3 Messinian in age. The sediments were deposited in a ramp depositional system. Sequence 1 is dominated by conglomerates and marls. In Sequence 2 and Sequence 3, carbonate deposits dominate in the inner ramp whereas siliciclastics preferentially occur in the middle and outer ramp. Bryomol carbonate sediments occur in all sequences whereas rhodalgal carbonates are restricted to Sequence 3. In bays protected from siliciclastic influx, rhodalgal deposits formed under transgressive conditions. A bryomol factory occurs in zones of continuous siliciclastic supply. This distribution results from facies partitioning during the flooding of the Ronda Basin, which has a rugged and irregular relief. Embayments were protected from siliciclastic influx and provided regions with less hydraulic energy.     

鲁西豫东地区奥陶纪岩相古地理特征及其演化*

鲁西豫东地区奥陶系碳酸盐岩地层是重要的石油和地下热水储集层。受限于基础地质资料,前人对鲁西豫东地区奥陶系层序划分存在争议,缺少对岩相古地理演化的精细刻画。为明确奥陶系层序地层特征与各期岩相古地理演化特征,通过对鲁西豫东地区周缘野外地质剖面考察、19口井岩心观察以及测井曲线特征分析,在层序地层格架内,对奥陶纪岩相古地理展布及其演化特征进行了研究。结果表明,根据层序界面类型和最大海泛面发育位置,研究区奥陶系可划分为SSQ1-SSQ2共2个二级层序和SQ1-SQ4共4个三级层序; 沉积相类型为海相碳酸盐岩台地,包括局限台地、开阔台地和蒸发台地3种亚相,并进一步细分为灰坪、颗粒滩、泥灰坪、灰-云坪、云坪、潟湖、含膏云坪和膏云坪8种沉积微相; 岩相古地理单元整体表现出陆表海的沉积建造特征,各期旋回性沉积为储集层叠置发育奠定了物质基础,云坪、膏云坪、含膏云坪、颗粒滩微相易于形成有利储集空间,是区域地热资源勘探开发的重点领域。     

Three-dimensional sequence analysis of a subsurface carbonate ramp, Mississippian Appalachian foreland basin, West Virginia, USA

Well‐cuttings, wireline logs and limited core and outcrop data were used to generate a regional, three‐dimensional sequence framework for Upper Mississippian (Chesterian), Greenbrier Group carbonates in the Appalachian foreland basin, West Virginia, USA. The resulting maps were used to document the stratigraphic response of the basin to tectonics and to glacio‐eustasy during the transition into ice‐house conditions. The ramp facies include inner ramp red beds and aeolianites, lagoonal muddy carbonates, mid‐ramp ooid and skeletal grainstone shoal complexes, and outer ramp wackestone–mudstone, that grades downslope into laminated silty lime mudstone. The facies make up fourth‐order sequences, a few metres to over 90 m (300 ft) thick. The sequences are bounded along the ramp margin by lowstand sandstones and calcareous siltstones. On the ramp, sequence boundaries are overlain by thin transgressive siliciclastics and aeolianites, and only a few are calichified. Maximum flooding surfaces on the outer ramp lie beneath deeper water facies that overlie lowstand to transgressive siliciclastic or carbonate units. On the shallow ramp, maximum flooding surfaces overlie siliciclastic‐prone transgressive systems tracts, that are overlain by highstand carbonates with significant grainstone units interlayered with lagoonal lime mudstones. The fourth‐order sequences are the major mappable subsurface units; they are bundled into weak composite sequences which are bounded by red beds. In spite of differential subsidence rates across the foreland basin (1 to 3 cm/k.y. up to 25 cm/k.y.), eustatic sea‐level changes controlled regional sequence development. Thrust‐load induced differential subsidence of fault‐blocks, coupled with in‐plane stress, controlled the rapid basinward thickening of the depositional wedge, whose thickness and facies were influenced by subtle structures such as arches trending at high angles as well as parallel to the margin.     

A Middle Ordovician Drowning Unconformity on the Northeastern Flank of the Okcheon (Ogcheon) Belt, South Korea

The Maggol Limestone of Ordovician age was deposited in the Taebaeksan (Taebacksan) Basin which occupies the northeastern flank of the Okcheon (Ogcheon) Belt of South Korea. Carbonate facies analysis in conjunction with conodont biostratigraphy suggests that an overall regression toward the top of the Maggol Limestone probably culminated in subaerial exposure of platform carbonates in the early Middle Ordovician (earliest Darriwilian). Elsewhere this subaerial exposure event is manifested as a major paleokarst unconformity at the Sauk-Tippecanoe sequence boundary beneath the Middle Ordovician succession and its equivalents, most in notably North America and North China. Due to its global extent, this paleokarst unconformity has been viewed as a product of second- or third-order eustatic sea level fall during the early Middle Ordovician. The Sauk-Tippecanoe sequence boundary in South Korea, however, appears to be a discrete marine-flooding surface in the upper Maggol Limestone. Strata beneath this surface represent by a thinning-upward stack of exposure-capped tidal flat-dominated cycles that are closely associated with multiple occurrences of paleokarst-related solution-collapse breccias. This marine-flooding surface is onlapped by a thick succession of thin-bedded micritic limestone that is eventually overlain by a Middle Ordovician condensed section. This physical stratigraphic relationship suggest that second- and third-order eustatic sea level fall may have been significantly tempered by regional tectonic subsidence near the end of Maggol deposition. The tectonic subsidence is also evidenced by the occurrence of coeval off-platform lowstand siliciclastic quartzite lenses as well as debris flow carbonate breccias (i.e., the Yemi Breccia) in the basin. With continued tectonic subsidence, a subsequent rise in the eustatic cycle caused drowning and deep flooding of the carbonate platform, forming a discrete marine-flooding surface that may be referred to as a drowning unconformity. This tectonic interpretation contrasts notably with the slowly subsiding carbonate platform model for the basin as has been previously suggested. Thus, it is proposed that the Taebaeksan Basin in the northeastern flank on the Okcheon Belt evolved from a slowly subsiding carbonate platform to a rapidly subsiding intracontinental rift basin during the early Middle Ordovician.     

A Middle Ordovician Drowning Unconformity on the Northeastern Flank of the Okcheon (Ogcheon) Belt,South Korea

The Maggol Limestone of Ordovician age was deposited in the Taebaeksan (Taebacksan) Basin which occupies the northeastern flank of the Okcheon (Ogcheon) Belt of South Korea. Carbonate facies analysis in conjunction with conodont biostratigraphy suggests that an overall regression toward the top of the Maggol Limestone probably culminated in subaerial exposure of platform carbonates in the early Middle Ordovician (earliest Darriwilian). Elsewhere this subaerial exposure event is manifested as a major paleokarst unconformity at the Sauk-Tippecanoe sequence boundary beneath the Middle Ordovician succession and its equivalents, most in notably North America and North China. Due to its global extent, this paleokarst unconformity has been viewed as a product of second- or third-order eustatic sea level fall during the early Middle Ordovician. The Sauk-Tippecanoe sequence boundary in South Korea, however, appears to be a discrete marine-flooding surface in the upper Maggol Limestone. Strata beneath this surface represent by a thinning-upward stack of exposure-capped tidal flat-dominated cycles that are closely associated with multiple occurrences of paleokarst-related solution-collapse breccias. This marine-flooding surface is onlapped by a thick succession of thin-bedded micritic limestone that is eventually overlain by a Middle Ordovician condensed section. This physical stratigraphic relationship suggest that second- and third-order eustatic sea level fall may have been significantly tempered by regional tectonic subsidence near the end of Maggol deposition. The tectonic subsidence is also evidenced by the occurrence of coeval off-platform lowstand siliciclastic quartzite lenses as well as debris flow carbonate breccias (i.e., the Yemi Breccia) in the basin. With continued tectonic subsidence, a subsequent rise in the eustatic cycle caused drowning and deep flooding of the carbonate platform, forming a discrete marine-flooding surface that may be referred to as a drowning unconformity. This tectonic interpretation contrasts notably with the slowly subsiding carbonate platform model for the basin as has been previously suggested. Thus, it is proposed that the Taebaeksan Basin in the northeastern flank on the Okcheon Belt evolved from a slowly subsiding carbonate platform to a rapidly subsiding intracontinental rift basin during the early Middle Ordovician.     

Stratal architecture and platform evolution of an early Frasnian syn‐tectonic carbonate platform,Canning Basin,Australia

Facies architecture and platform evolution of an early Frasnian reef complex in the northern Canning Basin of north‐western Australia were strongly controlled by syn‐depositional faulting during a phase of basin extension. The margin‐attached Hull platform developed on a fault block of Precambrian basement with accommodation largely generated by movement along the Mount Elma Fault Zone. Recognition of major subaerial exposure and flooding surfaces in the Hull platform (from outcrop and drillcore) has enabled comparison of facies associations within a temporal framework and led to identification of three stages of platform evolution. Stage 1 records initial ramp development on the hangingwall dip slope with predominantly deep subtidal conditions that prevented any cyclic facies arrangements. This stage is characterised by basal siliciclastic deposits and a major deepening‐upward facies pattern that is capped by a sequence boundary towards the footwall (north‐west) and a major flooding surface towards the hangingwall. Stage 2 reflects the bulk of platform aggradation, significant platform growth towards the hangingwall and the development of reef margins and cyclic facies arrangements. Thickening of this stage towards the hangingwall indicates that accommodation was generated by rotation of the fault block and overlying platform. Stage 3 records a major flooding and backstep of the platform margin. The Hull platform illustrates important elements of margin‐attached carbonate platforms in a half‐graben setting, including: (i) prominent, but limited, coarse siliciclastic input that does not have a major detrimental effect on carbonate production near the rift margin in arid to semi‐arid settings; (ii) wedge‐shaped accommodation created by syn‐depositional rotation of fault blocks and tilting of the hangingwall dip slope, resulting in shallow‐water facies and subaerial exposure up‐dip of the rotational axis and deeper water facies down‐dip; and (iii) evolution of a ramp to rimmed shelf, coincident with a sequence boundary–flooding surface, that is accelerated by tilting of the hangingwall dip slope during fault‐block rotation.     

塔里木盆地北缘阿克苏地区震旦系露头层序地层研究

本文对塔里木盆地北缘阿克苏地区磷矿沟震旦系剖面进行了详细的沉积体系研究。结果表明,该剖面主要发育滨岸沉积体系、碎屑岩潮坪沉积体系和碳酸盐潮坪沉积体系,这几种沉积体系的组合反映了震旦纪阿克苏地区由碎屑岩体系向碳酸盐岩体系的演化过程。在野外露头中共识别出4种不同类型的层序界面:(1)海侵上超层序不整合界面;(2)水进侵蚀冲刷面;(3)岩性、岩相转换面;(4)暴露溶蚀面。在识别出层序界面的基础上对震旦系划分出2个二级层序和5个三级层序。第一超层序SS1包含3个三级层序:SQ1、SQ2和SQ3。第二超层序SS2包含2个三级层序组:SQ4和SQ5。