淹没不整合型碳酸盐三级旋回层序——兼论碳酸盐台地的“凝缩作用”

与层序地层学定义的类型Ⅰ层序（ＬＳＴ＋ＴＳＴ＋ＣＳ＋ＨＳＴ）及类型Ⅱ层序（ＳＭＴ＋ＴＳＴ＋ＣＳ＋ＨＳＴ）不同，淹没不整合型碳酸盐三级旋回层序以凝缩段直接覆盖在层序界面之上形成的，“ＣＳ＋ＨＳＴ”序列为特征，而且其底界面为一淹没不整合面或加深饥饿间断面。该类型三级旋回层序是碳酸盐台地淹没事件产生的凝缩作用过程的产物，它以总体向上变浅的非对称相序为特征。华北北部晚寒武世地层中发育的四个淹没不整合型三级旋回层序的相序特征表明，台地淹没事件及其相关的凝缩作用，只要沉积背景适合，并非三级旋回层序所独有，高频率海平面变化也常产生“瞬时淹没”，因而凝缩段并非都发育在最大海侵期，并且凝缩段也存在级别归属问题。     

陆相断陷湖盆T—R旋回沉积层序与研究实例

陆相断陷湖盆的沉降机理、湖盆形态等均有别于其它类型的沉积盆地,因此,沉积层序的内部构成及层序边界发育特征也不同。在这种湖盆中,不适合于直接套用“Ｖａｉｌ学派”的被动大陆边缘型盆地的层序地层学模式,但其基本原理仍可应用。以东濮断陷盆地为例,分析了盆内构造－沉积旋回之内的湖进－湖退（Ｔ－Ｒ）旋回沉积层序,这种层序由湖进体系域（ＬＴＳＴ）与湖退体系域（ＬＲＳＴ）组成。ＬＲＳＴ中发育有各种不同类型的储集砂     

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     

晋中南沁水盆地早古生代海平面变化及其对碳酸盐岩储层的制约——以中阳城关剖面为例

以中阳城关剖面为例的层序地层学研究表明，晋中南沁水盆地下古生界由２个二级旋回组成，其界面为早奥陶世亮甲山组顶部的平行不整合面。这两个旋回的海面变化曲线形态具有区域乃至全球范围的可比性。由准层序堆叠方式确定的三级旋回具有区域性特点。难以进行全球范围内的对比。各层序均由海进体系域（ＴＳＴ）及高水位体系域（ＨＳＴ）构成，缺低水位体系域（ＬＳＴ）及海退体系域（ＲＳＴ）。潜在储层的发育主要是海退及低水位时期先期高水位体系域的白云石化及随之而发生的淡水淋滤形成的。因而本区储层的产出层位与层序界面具有强烈相关关系。作为     

湘鄂赣二叠系层序岩相古地理油气生储盖空间配置

沉积层序列的沉积体系域划分和层序岩相古地理图的编制,可用于油气生储盖层空间配置关系的研究分析,湘鄂赣地区不同类型的二叠纪盆地区可划分１１个沉积层序,包括下二叠统栖霞组（层序Ｓ１－Ｓ３）和茅口组（Ｓ４－Ｓ６）以及上二叠统吴家坪组或龙潭组（Ｓ７－Ｓ９）和长兴组（Ｓ１０,Ｓ１１）,每一层序又可划分出二三个ＨＳＴ,ＴＳＴ,ＬＳＴ或ＳＭＳＴ沉积体系域,根据编制的部分层序沉积体系域岩相古地理图,结合各体系域的     

米仓山西段晚元古代-古生代层序地层及地层模型

米仓山西段位于扬子地台北缘，该区除缺乏泥盆系和石炭系外，各时代地层均有发育。从震旦系灯影组至二叠系大隆（或长兴）组可划分出１３个相当于Ⅱ～Ⅲ级沉积旋回的层序或复合层序，并建立了地层模型。地台边缘的层序地层和沉积体系域具有它自身的某些特点。由局部构造活动引起的相对海平面变化，对沉积体系域和界面类型有着明显的影响。但是，在这种情况下形成的沉积序列和其它特征，与相应的典型体系域相比有一定的差异。为此，我们引用或引入了上超体系域（ＯＳＴ）、滨浅海边缘楔（ＳＭＷ）、最大海泛沉积层（ＭＦＳ）和Ⅲ类层序界面等概念。     

前陆盆地层序地层学研究中的几个问题

用层序地层学理论和工作方法来研究聚敛型活动大陆边缘的前陆盆地沉积地层时应力求使用术语上的统一,使用一级（旋回）层序、二级（旋回）层序、三级（旋回）层序等,每一级别的（旋回）层序可以划分低水位体系域、海（水）进体系域及高水位体系域、海（洪）泛面等。层序级别的划分以持续的时限为标准。各级别的层序界面以不整合面或沉积间断面或与之相应的整合面为标志。前陆盆地可容空间的变化主要受控于构造作用和全球海平面变化（假定物源供给稳定）。在造山构造活跃期,前陆挠曲作用占主导地位;在构造期后（构造宁静期）,全球海平面变化主要控制可容空间。这两种因素都以不同内容和形式在沉积层序中得到响应。通过详细的岩石学、沉积学、地层学以及各沉积区（前陆盆地即前渊、前隆和隆后盆地）剖面的区域对比研究,并与“标准”的全球海平面变化曲线图进行对比,可以区分出二者对前陆盆地形成、发育、演化的不同影响。     

断陷湖盆陡坡带陆相层序地层学模式研究─—以泌阳断陷双河─赵凹地区下第三系核三上段为例

以泌阳断陷双河－赵四地区下第三系核三上段陆相层序地层学研究为例,建立了断陆湖盆陡坡带陆相层序地层学模式：①陆相层序及其体系域界面模式;②体系域模式;③陆相层序地层模式。其中,陆相层序地层模式包括岩相格架模式及年代框架模式两个内容。研究结果显示,断陷湖盆陡坡带可识别出Ⅰ型和Ⅱ型两类陆相层序;一个完整的Ⅰ型陆相层序从下往上发育ＬＳＴ、ＴＳＴ、ＨＳＴ及ＲＳＴ四个体系域,共五个界面,除顶、底界面归属层序界面之外,其它三个界面皆为体系域界面;而Ⅱ型陆相层序缺失ＬＳＴ。无论何种体系域,其沉积体的几何形状均为模状体,且各体系域的沉积相横向配置呈现规律性变化。陆相层序地层等时框架模式清晰地显示了研究区下第三系核三上段的沉积充填史及其沉积层序时空展布特征。     

安徽南部下扬子地区寒武系露头层序地层初步研究

露头层序地层研究表明，安徽下杨子地区寒武纪可识别出两个Ⅰ类层序及三个Ⅱ类层序，早寒武世的三个Ⅱ类层序由于同沉积断裂影响陆架边缘体系域不甚发育；中、晚寒武世的两个Ⅰ类层序由低水位体系域、海侵体系域及高水位体系域构成。由沉积体系域演化作出的海平面变化曲线不同于Ｖａｉｌ的寒武纪全球海平面变化Ⅱ级旋回，表明了皖南下扬子海盆的海平面升降受扬子板块、华夏板块的影响远大于全球海平面变化幅度。     

徐州贾汪地区中—上寒武统藻礁,风暴层与海平面变化

笔者详细研究了徐州贾汪地区中－上寒武统的二郎山等剖面,将张夏组－凤山组划分为３个各具特色的三级层序,根据各层序内副层序的堆叠形式进一上划分出海侵体系域（ＴＳＴ）凝缩段（ＣＳ）及高位体系域（ＨＳＴ）其中张夏层序的藻礁为中－晚寒武世期间发育的最大规模碳酸盐岩缓坡藻礁,崮山层序凝胶缩代表中－晚寒武世最大海泛（海侵）期沉积,长山－凤山层序顶部白云岩代表中－晚寒武世最小海平面（海退）时期的沉积。     

Facies and sequence stratigraphic analysis in an intracratonic, thermal-relaxation basin: the Early Proterozoic, Lower Quilalar Formation and Ballara Quartzite, Mount Isa Inlier, Australia

The Quilalar Formation and correlative Mary Kathleen Group in the Mount Isa Inlier, Australia, conformably overlie rift-related volcanics and sediments and non-conformably overlie basement rocks. They represent a thermal-relaxation phase of sedimentation between 1780 and 1740 Ma. Facies analysis of the lower siliciclastic member of the Quilalar Formation and the coeval Ballara Quartzite permits discrimination of depositional systems that were restricted areally to either N-S-trending marginal platform or central trough palaeogeographic settings. Four depositional systems, each consisting of several facies, are represented in the lower Quilalar Formation-Ballara Quartzite; these are categorized broadly as storm-dominated shelf (SDS), continental (C), tide-dominated shelf (TDS) and wave-dominated shoreline (WDS). SDS facies consist either of black pyritic mudstone intervals up to 10 m thick, or mudstone and sandstone associated in 6–12-m-thick, coarsening-upward parasequences. Black mudstones are interpreted as condensed sections that developed as a result of slow sedimentation in an outer-shelf setting starved of siliciclastic influx. Vertical transition of facies in parasequences reflects flooding followed by shoaling of different shelf subenvironments; the shoreface contains evidence of subaerial exposure. Continental facies consist of fining-upward parasequences of fluvial origin and tabular, 0·4–4-m-thick, aeolian parasequences. TDS facies are represented by stacked, tabular parasequences between 0·5 and 5 m thick. Vertical arrangement of facies in parasequences reflects flooding and establishment of a tidal shelf followed by shoaling to intertidal conditions. WDS facies are preserved in 0·5–3-m-thick, stacked, tabular parasequences. Vertical transition of facies reflects initial flooding with wave reworking of underlying arenites along a ravinement surface, followed by shoaling from lower shoreface to foreshore conditions. Parasequences are stacked in retrogradational and progradational parasequence sets. Retrogradational sets consist of thin SDS parasequences in the trough, and C, TDS and probably WDS parasequences on the platforms. Thick SDS parasequences in the trough, and TDS, subordinate C and probably WDS parasequences on the platforms make up progradational parasequence sets. Depositional systems are associated in systems tracts that make up 40–140-m-thick sequences bounded by type-2 sequence boundaries that are disconformities. Transgressive systems tracts consist of C, TDS and probably WDS depositional systems on the platforms and the SDS depositional system and suspension mudstone deposits in the trough. The transgressive systems tract is characterized by retrogradational parasequence sets and developed in response to accelerating rates of sea-level rise following lowstand. Condensed-section deposits in the trough, and the thickest TDS parasequences on the platforms reflect maximum rates of sea-level rise and define maximum flooding surfaces. Highstand systems tract deposits are progradational. Early highstand systems tracts are represented by TDS and probably WDS depositional systems on the platforms and suspension mudstone deposits in the trough and reflect decreasing rates of sea-level rise. Later highstand systems tracts consist of the progradational SDS depositional system in the trough and, possibly, thin continental facies on the platforms. This stage of sequence development is related to slow rates of sea-level rise, stillstand and slow rates of fall. Lowstand deposits of shelf-margin systems tracts are not recognized but may be represented by shoreface deposits at the top of progradational SDS parasequence sets.     

Stacked fluvial and tide-dominated estuarine deposits in high-frequency (fourth-order) sequences of the Eocene Central Basin, Spitsbergen

Eighteen coastal-plain depositional sequences that can be correlated to shallow- to deep-water clinoforms in the Eocene Central Basin of Spitsbergen were studied in 1 × 15 km scale mountainside exposures. The overall mud-prone (>300 m thick) coastal-plain succession is divided by prominent fluvial erosion surfaces into vertically stacked depositional sequences, 7–44 m thick. The erosion surfaces are overlain by fluvial conglomerates and coarse-grained sandstones. The fluvial deposits show tidal influence at their seaward ends. The fluvial deposits pass upwards into macrotidal tide-dominated estuarine deposits, with coarse-grained river-dominated facies followed further seawards by high- and low-sinuosity tidal channels, upper-flow-regime tidal flats, and tidal sand bar facies associations. Laterally, marginal sandy to muddy tidal flat and marsh deposits occur. The fluvial/estuarine sequences are interpreted as having accumulated as a series of incised valley fills because: (i) the basal fluvial erosion surfaces, with at least 16 m of local erosional relief, are regional incisions; (ii) the basal fluvial deposits exhibit a significant basinward facies shift; (iii) the regional erosion surfaces can be correlated with rooted horizons in the interfluve areas; and (iv) the estuarine deposits onlap the valley walls in a landward direction. The coastal-plain deposits represent the topset to clinoforms that formed during progradational infilling of the Eocene Central Basin. Despite large-scale progradation, the sequences are volumetrically dominated by lowstand fluvial deposits and especially by transgressive estuarine deposits. The transgressive deposits are overlain by highstand units in only about 30% of the sequences. The depositional system remained an estuary even during highstand conditions, as evidenced by the continued bedload convergence in the inner-estuarine tidal channels.     

华北石炭-二叠纪层序地层格架及其特征

华北石炭二叠纪沉积建造由两部分组成,下部为碳酸盐岩与硅质碎屑岩构成的含煤建造,上部为硅质碎屑岩红色建造。根据不整合面及其它识别层序界面的标志,该沉积建造可划分为５个沉积层序。ＤＳ_１、ＤＳ_２、ＤＳ_３层序属陆表海型层序,其底界面为Ⅰ_ｅ型层序界面,层序内仅发育海侵体系域和高位体系域;ＤＳ_４层序为过渡型层序,由低位体系域、海侵体系域和高位体系域构成;ＤＳ_５层序为湖泊型层序,包括低水位体系域、水进体系域和高位体系域。盆地充填超层序（ＤＳ_１-ＤＳ_５）的发育受控于全球二级相对海平面变化,而沉积层序的发育则与区域性造山作用引起的三级海平面变化有关。     

Sequence stratigraphy in a mixed carbonate-silicilastic depositional system (Middle Miocene; Styrian Basin,Austria)

The mixed carbonate-siliciclastic Weißenegg (Allo-) Formation records three depositional sequences corresponding approximately to the TB 2.3, TB 2.4 and TB 2.5 global cycles. Sea-level fluctuations were of the order of at least 30 m. Siliciclastic lowstand systems tracts comprise lignite deposits, reworked basement and tidal siltstones (above a tectonically enhanced sequence boundary) as well as coastal sand bars. Coastal sands of the transgressive systems tract contain distinct layers of well cemented nodules. They are interpreted as the first stage in hardground formation and record superimposed minor sea-level fluctuations. Coral patch reefs and rhodolith platforms developed during transgressive phases and were subsequently drowned and/or suffocated by siliciclastics during early highstand. Shallowing upwards siliciclastic parasequences, each terminated by a bank of rhodolith limestone, form the (late) highstand systems tract. The limestone beds record superimposed fourth-order transgressive pulses. Occasionally a carbonate highstand wedge developed. Lowstand carbonate shedding occurred where the top of a platform which suffered incipient drowning during highstand was near sealevel again during the following lowstand. Late highstand delta progradation is common.     

Depositional facies,environments and sequence stratigraphic interpretation of the Middle Triassic–Lower Cretaceous (pre-Late Albian) succession in Arif El-Naga anticline,northeast Sinai,Egypt

The Middle Triassic–Lower Cretaceous (pre-Late Albian) succession of Arif El-Naga anticline comprises various distinctive facies and environments that are connected with eustatic relative sea-level changes, local/regional tectonism, variable sediment influx and base-level changes. It displays six unconformity-bounded depositional sequences. The Triassic deposits are divided into a lower clastic facies (early Middle Triassic sequence) and an upper carbonate unit (late Middle- and latest Middle/early Late Triassic sequences). The early Middle Triassic sequence consists of sandstone with shale/mudstone interbeds that formed under variable regimes, ranging from braided fluvial, lower shoreface to beach foreshore. The marine part of this sequence marks retrogradational and progradational parasequences of transgressive- and highstand systems tract deposits respectively. Deposition has taken place under warm semi-arid climate and a steady supply of clastics. The late Middle- and latest Middle/early Late Triassic sequences are carbonate facies developed on an extensive shallow marine shelf under dry-warm climate. The late Middle Triassic sequence includes retrogradational shallow subtidal oyster rudstone and progradational lower intertidal lime-mudstone parasequences that define the transgressive- and highstand systems tracts respectively. It terminates with upper intertidal oncolitic packstone with bored upper surface. The next latest Middle/early Late Triassic sequence is marked by lime-mudstone, packstone/grainstone and algal stromatolitic bindstone with minor shale/mudstone. These lower intertidal/shallow subtidal deposits of a transgressive-systems tract are followed upward by progradational highstand lower intertidal lime-mudstone deposits. The overlying Jurassic deposits encompass two different sequences. The Lower Jurassic sequence is made up of intercalating lower intertidal lime-mudstone and wave-dominated beach foreshore sandstone which formed during a short period of rising sea-level with a relative increase in clastic supply. The Middle-Upper Jurassic sequence is represented by cycles of cross-bedded sandstone topped with thin mudstone that accumulated by northerly flowing braided-streams accompanying regional uplift of the Arabo–Nubian shield. It is succeeded by another regressive fluvial sequence of Early Cretaceous age due to a major eustatic sea-level fall. The Lower Cretaceous sequence is dominated by sandy braided-river deposits with minor overbank fines and basal debris flow conglomerate.     

泌阳断陷陆相层序外部构型研究

摘 要　 泌阳断陷陆相层序外部构型研究包括层序级别的厘定与划分以及界面的类型及其识 别标志。陆相层序构成单元可分为8个级别‚前4级属低频层序‚后4级为高频层序。泌阳 断陷湖盆的3类盆地原型‚分别形成了3套盆地充填序列及其所对应的3个构造层序 （Ⅰ‚ Ⅱ‚Ⅲ）;构造层序Ⅱ为该断陷湖盆的沉积充填主体‚可进一步划分为7个层序组‚其中在层 序组Ⅱ D （即核三段上） 中可识别出3个层序。陆相层序的体系域具四分性：低水位体系域、 水进体系域、高水位体系域及水退体系域;小层序组有4种基本类型：进积小层序组、低位 加积小层序组、退积小层序组和高位加积小层序组。     

鄂尔多斯盆地东北缘晚古生代陆表海含煤岩系层序地层研究

通过区域不整合面、沉积体系转换面、构造应力场转换面和水上暴露面等层序界面的识别,对研究区进行层序地层划分,指出鄂尔多斯盆地东北缘晚古生代陆表海含煤岩系发育7个三级层序。在此基础上,认为陆表海层序仍然具有“三元”结构,由低位体系域、海侵体系域和高位体系域组成。在盆地北部发育的多期河道砂岩具有低位体系域的下切谷充填特点——面状充填,如晋祠砂岩、桥头砂岩以及北岔沟砂岩等。煤层在层序格架中的定位与海平面变化的转换时期有关,主要发育在陆表海环境的海侵体系域下部以及陆相环境的高位体系域上部。     

山东黄县盆地古近系李家崖组含煤岩系沉积相特征及演化

山东黄县盆地是中国东部一个重要的煤和油页岩共生盆地,古近系李家崖组是盆地主要的含煤岩系发育层段。根据层序地层学理论,建立了古近系层序地层格架;依据钻测井、岩心资料划分了李家崖组的沉积相类型,编制了分体系域的沉积相图。主要结论如下:(1)李家崖组发育湖泊、辫状河三角洲以及扇三角洲3种沉积相类型。(2)层序Ⅰ低水位体系域以辫状河三角洲相为主,湖扩展体系域以扇三角洲相和湖泊相为主,高水位体系域以扇三角洲相为主;层序Ⅱ低水位体系域以辫状河三角洲相为主,湖扩展体系域以扇三角洲相和湖泊相为主,高水位体系域以湖泊相为主。(3)层序Ⅰ发育时期: 低水位期盆地初始形成—湖扩展期盆地扩张—高水位期盆地萎缩;层序Ⅱ发育时期: 低水位期盆地再次缓慢扩张—湖扩展期盆地加速扩张—高水位期盆地萎缩消亡。     

Early Miocene lacustrine deposits and sequence stratigraphy of the Ermenek Basin,Central Taurides,Turkey

The lacustrine Ermenek Basin evolved as a SE-trending intramontane graben affected by strike–slip deformation, with the initial two lakes merging into one and receiving sediment mainly through fan deltas sourced from the basin's southern margin. The northern margin was a high-relief rocky coast with a wave-dominated shoreline. The Early Miocene lacustrine sedimentation was terminated by a late Burdigalian marine invasion that drowned the basin and its surroundings. The lacustrine basin-fill succession is up to 300 m thick and best exposed along the southern margin, where it consists of four sequences bounded by surfaces of forced regression. The offshore architecture of each sequence shows a thin lowstand tract of shoreface sandstones overlain by a thick transgressive systems tract of mudstones interbedded with sandy tempestites and delta-derived turbidites, which form a set of coarsening-upward parasequences representing minor normal regressions. The corresponding nearshore sequence architecture includes a thick lowstand tract of alluvial-fan deposits overlain by either a well-developed transgressive systems tract (backstepping parasequence set or single fan-deltaic parasequence) and poorly preserved highstand tract; or a thin transgressive tract (commonly limited to flooding surface) and a well-developed highstand tract (thick fan-deltaic parasequence). The sequences are poorly recognizable along the northern margin, where steep shoreline trajectory rendered the nearshore system little responsive to lake-level changes. The resolution of local stratigraphic record thus depends strongly upon coastal morphology and the character of the depositional systems involved.The sequential organization of the basin-fill succession reflects syndepositional tectonics and climate fluctuations, whereas the lateral variation in sequence architecture is due to the localized sediment supply (deltaic vs. nondeltaic shoreline), varied coastal topography and differential subsidence. The study points to important differences in the sequence stratigraphy of lacustrine and marine basins, related to the controlling factors. A crucial role in lacustrine basin is played by climate, which controls both the lake water volume and the catchment sediment yield. Consequently, the effects of tectonics and the dynamics of changes in accommodation and sediment supply in a lacustrine basin are different than in marine basins.     

准西车排子地区中新生界层序格架及砂体预测模式

前陆盆地由于其独特的构造和沉积背景形成不同的层序地层格架样式.以准噶尔盆地车排子地区为例,详细分析了造山带前缘隆起斜坡带层序样式.在准西车排子地区中新生界主要目的层段(下白垩统吐谷鲁群、古近系安集海河组、新近系沙湾组和塔西河组)充填沉积中识别出5条主要等时界面,据界面的性质和级别划分出一级层序2个,二级层序组3个,三级层序4个.受前陆盆地造山带前缘隆起斜坡带独特的沉积背景及多幕逆冲构造活动作用过程的控制,准西车排子地区中新界各三级层序具有二元沉积结构特征,仅发育低位和湖扩体系域.逆冲挤压期发育低位粗碎屑沉积,应力松弛期发育湖扩细碎屑沉积.低位下切谷、大型扇三角洲和湖扩滩坝砂是准西车排子地区的有利储集砂体及勘探目标.