陕北佳县石炭-二叠系层序地层研究

利用钻孔岩心资料,对陕北佳县石炭-二叠纪进行了层序地层学的分析。依据关键界面的层序界面、海侵面、最大海泛面等特征,对沉积环境的演化及相变特征进行分析研究,在石炭-二叠系中划分出了21个四级层序,组合为21个层序组、6个复合层序,并论述了该地区石炭-二叠系层序的特征。     

广东省二叠纪含煤岩系层序地层特征

根据野外剖面实测、室内岩矿鉴定及综合作图等,对广东省二叠纪含煤岩系层序地层特征进行分析,识别出区域不整合面、下切谷冲刷面、古土壤层、事件界面、沉积相转换面5个类型、共6个三级层序界面,划分为5个三级层序。S1～S5各层序底界面的代表界面分别为广花地区K1砂岩底面、广花地区K2砂岩底面、连阳地区灰岩不整合面、连阳地区白灰岩段底面和广花地区圣堂组大套砂岩底面;S5的顶界面为二叠系与三叠系之间的构造事件面。对比不同地区后发现,广花和兴梅两个地区的层序发育特征较为类似,连阳地区5个层序的变化呈现了海侵(S1、S2)-快速海退-海侵(S3)-缓慢海退(S4、S5)的旋回过程,而曲仁地区的5个层序特征类似、变化较小。与20世纪90年代层序地层划分方案对比,有2个层序界面与本次划分的层序界面相同。     

松南西斜坡前缘带青山口组层序界面识别及特征研究

在前人研究的基础上,应用高分辨层序地层学理论与研究方法,对松辽盆地南部西斜坡地区的青山口组地层进行了层序地层划分与对比工作,从中识别出6个具等时意义的层序界面,将其划分为5个中期基准面旋回(4级层序)。建立了层序界面的岩心识别标志,即旋回叠加样式的变化面、岩性突变面—冲刷面、相类型的变化面和暴露剥蚀面,在测井曲线上,层序界面位于测井曲线幅度发生明显变化或曲线组合型式的转换处,在研究区地震剖面上的层序界面识别标志(超削反射终止特征)不明显。根据层序划分和层序界面的识别标志,把4级层序界面划分为不整合面、沉积作用转换面和顶超面,并对层序界面特征进行了详细研究。确定了研究层段湖泛面包括三角洲体系—湖泛面、深水湖—浊积体系—湖泛面和河流体系—洪泛面3种类型。层序界面和湖泛面的识别和确定,对于研究区高分辨率层序地层格架的建立和对储层分布规律的研究与预测具有重要意义。     

下扬子区二叠系层序地层格架

针对研究区钻及二叠系的井甚少,现有的几条地震剖面质量欠佳的状况,采用露头层序地层学的方法在８条主干剖面、数十条辅助剖面详细研究的基础上将研究区二叠系划分为１１个Ⅲ级层序（栖霞阶为３个层序,茅口阶为３个层序,吴家坪阶为３个层序和长兴阶为２个层序）。以具区域性分布的生物化石带为主,辅以岩性组合、岩相特征、垂向相序特点及地质事件,对研究区二叠系进行详细区域层序对比,总结了二叠系层序特点。     

贵州水城矿区上二叠统层序地层及控煤作用

贵州西部水城矿区主要的含煤地层晚二叠世龙潭组为典型的海陆过渡相含煤岩系,其沉积环境有下三角洲平原、潮坪和泻湖等。作者对水城矿区上二叠统含煤岩系龙潭组和汪家寨组层序地层进行了分析,共识别出4个层序界面,并根据层序界面将水城矿区上二叠统划分为3个层序地层,层序Ⅰ从峨眉山玄武岩顶界到标七底界;层序Ⅱ从标七底界开始到四号煤层底板;层序Ⅲ从四号煤层底板开始到二叠系与三叠系的不整合面。三个层序地层中层序Ⅱ煤层发育最好,层序Ⅲ次之,层序Ⅰ最差。在层序中又进一步划分出低位体系域、海侵体系域和高位体系域,其中尤以海侵体系域最有利成煤作用,高位体系域次之,低位体系域最差。     

塔里木轮南油田三叠系层序与岩性圈闭

塔里木板块轮南井区三叠系为典型的克拉通内凹陷盆地型陆相碎屑岩,主要由湖泊和三角洲沉积体系构成产油层系。层序单元的划分对比是岩性油气藏圈定的核心技术,以测井和三维地震资料为依据建立井震合一的层序地层格架,所划分的3个层序8个体系域控制了三套区域性和多套局部性储盖组合。区域性储盖组合以层序为单元,层序下部的低位体系域和湖侵体系域砂岩组成区域性储层,上部高位体系域的湖相和三角洲相泥岩为区域性盖层,以构造圈闭为主;局部性储盖组合以体系域为单元,由同一体系域的砂岩和邻近泥岩组成,以岩性圈闭为主。结合地震储层预测技术可划定新的岩性地层圈闭,高位体系域期和湖侵体系域中发育的局部性储盖组合是岩性地层圈闭勘探的重点。     

扬子地块西北缘二叠系-中三叠统层序地层与沉积相展布

扬子地块西北缘二叠系-中三叠统以大套碳酸盐岩地层为主。本文应用碳酸盐岩层序地层学理论和方法,通过地震、露头、岩心和测井资料分析,在二叠系-中三叠统识别出升隆侵蚀不整合面、海侵上超层序不整合面、水下沉积间断层序不整合面、局部暴露层序不整合面等4种沉积层序界面,并将二叠系-中三叠统划分为11个三级层序23个体系域。通过层序地层对比,建立了研究区层序地层格架,在格架内分析了不同体系域的沉积相特征,认为台缘礁滩相和台内滩相为有利储集相带,且前者主要发育于层序Ⅰ的高位体系域(栖霞组),以及层序Ⅴ和层序Ⅵ的海浸体系域(长兴组和飞仙关组)。     

准噶尔盆地西北缘三叠系层序地层与隐蔽油气藏勘探

层序地层学及层序地层原理指导下的地震资料解释为地层、岩性油气藏勘探提供了理论和技术支持。为配合准噶尔盆地西北缘油气勘探从克乌断裂带上盘向下盘、从构造油气藏向地层、岩性等隐蔽油气藏的转变,利用陆相层序地层学理论和地球物理资料,将三叠系划分为1个二级层序、5个三级层序和8个体系域,进而总结出拗陷完整型和拗陷残缺型两种层序类型。结合测井约束地震反演和井间沉积对比,探讨了三叠系砂体结构和湖侵体系域地层超覆、湖退体系域及最大湖泛面附近小规模滑塌浊积体岩性透镜体等5种圈闭发育模式。油气成藏综合条件分析指出有效圈闭和油源断层的识别是制约斜坡带岩性油气藏勘探的关键。     

四川盆地上三叠统构造层序划分及盆地演化

晚三叠世是四川盆地演化的重要时期。根据野外露头、钻井和地震资料,运用构造层序地层学的思路和方法,对四川盆地上三叠统层序界面、层序划分和层序特征进行深入研究,并建立层序地层格架。研究表明,四川盆地上三叠统可识别出4个层序界面:1)上三叠统与中、下三叠统之间的区域性构造不整合面;2)须二段与小塘子组的分界面;3)须三段与须四段之间的次级构造不整合面;4)三叠系与侏罗系之间的区域性构造不整合面。根据层序界面的发育情况,将研究区划分为3个构造层序,每个层序以最大湖泛面为界,划分为盆地扩张体系域(BE)和盆地收缩体系域(BW)2个体系域。晚三叠世四川盆地的演化主要是川西前陆盆地的演化,其中TS1为边缘前陆盆地演化阶段;TS2为川西前陆盆地形成阶段,龙门山逆冲推覆体开始逆冲推覆;TS3为川西前陆盆地发展阶段,受安县运动的影响,龙门山逆冲褶皱成山,使得整个四川盆地进入了陆相沉积环境。构造运动是控制晚三叠世四川盆地演化的重要因素。     

塔里木盆地台盆区三叠系三级层序界面和体系域界面的识别与应用

尽管前人对塔里木盆地塔北地区三叠系进行过沉积与层序地层研究,但是有关全盆范围内层序地层格架研究比较少见。应用现代沉积学和层序地层学的原理和方法,着眼于塔里木盆地台盆区的整体研究,综合利用地震、钻井、测井及分析化验等资料,对研究区三叠系三级层序界面和体系域界面进行识别,共识别出5个具有等时意义的层序界面,对应划分为4个三...     

Permian and Triassic Sequence Stratigraphy and Sea Level Changes of Eastern Yangtze Platform

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二叠系-三叠系研究的进展

介绍了近年来二叠系、三叠来年代地层学的研究趋势及最新的年代地层表与磁性地层表。在二叠系、三叠系界线方面报道了新的底界方案及四个层型候选剖面，以及与之有关的生物地层学进展。界线事件地层学的总趋势是球外事件研究趋于沉静而缺氧事件、海侵事件及火山事件的综合作用导致生物大绝灭的观点已占主导地位，其中界线缺氧事件的确立以及海侵始于二叠纪末的新观点是引人注目的发展。在层序地层学方面对于二叠系的全球海平面变化一般趋向于分四个旋回，但对于三叠纪则尚未统一。早二叠世的全球冰期—海平面升降旋回及三叠纪的米兰柯维奇旋回在我国均有可能发现和研究。文章最后提出了层序地层界线与年代地层界线不一致所产生的理论问题并探讨了解决方法。     

Normal fault linkage and reactivation,Dampier Sub-basin,Western Australia

The Northern Carnarvon Basin of Western Australia has experienced a polyphase deformation history during the breakup of Gondwana. Extension during the Carboniferous–Permian and a subsequent Early Jurassic rift event imposed two distinct fault systems, separated by a several kilometre-thick Triassic sedimentary sequence. Inboard areas, where Triassic sequences are thinner, Jurassic faults both detach above and also penetrate into Permian sequences. Other large-scale faults demonstrate a vertical hard/soft linkage between the two fault systems. In outboard areas where the Triassic is thicker, the relationship is less clear owing to the lower resolution of Permian sequences in seismic data. Here we undertake fault displacement analysis on three faults on the southern margin of the Exmouth Plateau to investigate the growth mechanism of Jurassic-aged faults and possible structural influence of deeper Permian faults. We find evidence of low-throw faults restricted to Mesozoic strata as more complex-segmented faults that have nucleated at a depth below that resolvable on seismic data. When considered in a regional context, the nature of faults in this study suggest oblique reactivation of the NE-trending Permian fabric, under east–west-oriented extension.     

鄂尔多斯盆地陕北地区上三叠统延长组不同级次层序界面的识别

以高分辨率层序地层学理论为指导,通过对鄂尔多斯盆地陕北地区上三叠统延长组典型露头剖面及岩心观察、描述的基础上,结合大量测井曲线,详细地分析了延长组不同级次层序界面的识别标志。结果表明:鄂尔多斯盆地陕北地区上三叠统延长组由1个超长期旋回,4个长期旋回,9个中期旋回及若干个短期旋回组成。由于印支运动的影响,在研究区形成了两个区域性的构造运动升降面(SLSB2和SLSB1),该界面为超长期旋回的顶、底界面。长期旋回层序为一套区域性湖进-湖退沉积序列,界面是低角度的侵蚀不整合面和与其相应的整合面。研究区3个长期旋回层序界面自下而上依次为:区域性基准面抬升所形成的水进界面,相当于"李家畔页岩";区域性的泥岩、凝灰岩标志层,相当于长6油层组底部的k2标志层;区域性的相转换界面,相当于长4 5和长3的分界面。中期旋回和短期旋回层序界面主要为不同级次的湖泛面、冲刷侵蚀面、岩石类型或相组合的转换面、岩石相内部的层理变化界面、砂泥岩厚度旋回性变化界面等。在界面识别的基础上,对研究区沉积旋回及界面的空间配置进行了分析,认为不同级次界面的识别是高精度层序地层研究的核心,对于油田勘探和开发具有至关重要的作用。     

Geological Characteristics and Manifestations of Geological Processes of Sequence Boundaries and Their Vicinities

This paper discusses the geological characteristics and architectures of sequence boundaries and their vicinities and has proposed a classification scheme for the sequence boundaries, which can thus be grouped into three types and eight categories: type I includes exposed truncated surface, palaeosol surface, palaeokarst surface and exposed surface; type Ⅱ boundaries include structural transitional surface during sea-level fall and transgressive onlap surface; and type Ⅲ includes submarine erosional diagenetic diastem and event surface. A study has been made for the three major boundaries lying between the Permian and pre-Permian, the Permian and Triassic, and the Middle and Lower Triassic respectively in terms of multiple disciplines such as lithostratigraphy, biostratigraphy, magnetostratigraphy and carbon and oxygen isotopic geology. These three boundaries are ascribed to type I , typeⅡ and typeⅢ, respectively.     

三江北段东莫扎抓矿区构造变形特征

已有关于青藏高原隆升的各种构造模型多重视新生代变形而忽略了早期构造变形的限制.本文以三江北段东莫扎抓矿区为研究对象,通过详细的构造-岩相填图,恢复了矿区二叠纪以来变形序列,结合区域资料讨论了变形事件的大地构造背景.研究表明矿区发育中-下二叠统九十道班组灰岩、上二叠统那益雄组碎屑岩、上三叠统结扎群甲丕拉组碎屑岩和上三叠统结扎群波里拉组灰岩4套地层系统,二叠系与三叠系之间为不整合接触,局部被近南北向逆断层代替.北西向逆断层横亘矿区,断层上盘三叠纪碎屑岩和灰岩整体北倾,断层下盘三叠纪岩石被左右两条走滑断层夹持向南挤出.在图面和露头尺度上矿区叠加褶皱明显,南北向剖面上多见紧闭的倾伏褶皱,近东西向剖面上则为开阔水平的斜歪褶皱,表明南北向剖面上观察到的是已被叠加的早期褶皱,为矿区第一期变形,其形成与三叠纪末古特提斯洋盆闭合有关.始新世晚期印-亚大陆碰撞地壳缩短形成矿区第二期构造,即北西向逆断层和褶皱叠加.第三期近南北向逆断层可能形成于始新世末,与印-亚大陆碰撞引起的侧向旋转有关.     

四川盆地西北部二叠系栖霞阶层序地层特征及地质意义

基于露头、钻井岩心和测录井资料,采用层序地层学理论与方法,将四川盆地西北部二叠系梁山组+栖霞组作为一个整体予以解剖,识别出梁山组底界面(Ⅰ型)、栖一段与栖二段界面(Ⅱ型)和栖霞组与茅口组界面(Ⅰ型)3个三级层序界面,将中二叠统栖霞阶划分为2个三级层序: 下部的SQ1层序对应梁山组+栖一段,上部的SQ2层序对应栖二段。通过栖霞阶层序地层格架分析,发现栖霞阶地层存在“底超顶削”的充填规律,统计并绘制SQ1与SQ2层序地层厚度等值线图,对研究区栖霞阶SQ1初期和SQ2期构造—古地理格局进行了恢复,在明确SQ2期为栖霞阶主要成滩期的基础上,结合岩溶发育单元及白云岩展布特征,讨论栖霞阶油气储集意义。结果表明:区内栖霞阶存在北西、北东向隆坳分异,汉南隆起、川北隆起、北缘隆起与广元—旺苍凹陷始终控制了区内沉积格局,指出广元—旺苍海槽雏形始于二叠系栖霞阶。研究区岩溶白云岩孔洞型储集层区与环广元—旺苍凹陷周缘的灰岩岩溶型储集层区为有利的勘探区。     

Sequence stratigraphic characteristics and geological significance of the Permian Qixia Stage in northwestern Sichuan Basin

Based on outcrops, drilling, cores, and logging data, the Liangshan Formation and Qixia Formation in the northwestern Sichuan region are analyzed using the theory and method of sequence stratigraphy. Three third-order sequence boundaries are identified, including the basal boundary of Liangshan Formation (type Ⅰ), the boundary between Qi 1 Member and Qi 2 Member (type Ⅱ), and the boundary between the Qixia Formation and the Maokou Formation (type Ⅰ). The Middle Permian Qixia Stage can be subdivided into two third-order sequences (from base to top: SQ1 and SQ2). The SQ1 sequence corresponds to the Liangshan Formation and the Qi 1 Member, and the SQ2 sequence corresponds to the Qi 2 Member. Based on the sequence stratigraphic framework reconstruction of the Qixia Stage, the sedimentary filling pattern of the “onlapping at the base and truncation at the top” is discovered. The contour maps of SQ1 and SQ2 sequence stratigraphic thickness are calculated and plotted. Combined with the stratigraphic filling pattern, the tectonic-palaeogeographical framework of the early SQ1 and SQ2 phases of the Qixia Stage, their geological significance is discussed. At the Qixia Stage, the differentiation between uplift and depression occurs in the northwest and northeast trends. The Hannan uplift, the northern Sichuan uplift, the northern margin uplift and the Guangyuan-Wangcang sag have controlled the sedimentary pattern in the study area. It is indicated that prototype of the Guangyuan-Wangcang Trough began in the Middle Permian Qixia Stage. In the study area, the karst cave-type dolostone reservoir and the karst-type limestone reservoir around the Guangyuan-Wangcang sag rim are favorable exploration areas.     

The terminal Permian in European Russia: Vyaznikovian Horizon,Nedubrovo Member,and Permian–Triassic boundary

The comprehensive analysis of the data obtained on terrestrial vertebrata, ostracods, entomologic fauna, megaflora, and microflora in deposits of the Vyaznikovian Horizon and Nedubrovo Member, as well as the paleomagnetic data measured in enclosing rocks, confirms heterogeneity of these deposits. Accordingly, it is necessary to distinguish these two stratons in the terminal Permian of the East European Platform. The combined sequence of Triassic–Permian boundary deposits in the Moscow Syneclise, which is considered to be the most complete sequence in the East European Platform, is as follows (from bottom upward): Vyatkian deposits; Vyaznikovian Horizon, including Sokovka and Zhukovo members; Nedubrovo Member (Upper Permian); Astashikha and Ryabi members of the Vokhmian Horizon (Lower Triassic). None of the sequences of Permian–Triassic boundary deposits known in the area of study characterizes this sequence in full volume. In the north, the Triassic deposits are underlain by the Nedubrovo Member; in the south (the Klyazma River basin), the sections are underlain by the Vyaznikovian Horizon. The Permian–Triassic boundary adopted in the General Stratigraphic Scale of Russia for continental deposits of the East European platform (the lower boundary of the Astashikha Member) is more ancient than the one adopted in the International Stratigraphic Chart. The same geological situation is observed in the German Basin and other localities where Triassic continental deposits are developed. The ways of solving this problem are discussed in this article.     

BASIN-RANGE TRANSITION AND GENETIC TYPES OF SEQUENCE BOUNDARY OF THE QIANGTANG BASIN IN NORTHERN TIBET

BASIN-RANGE TRANSITION AND GENETIC TYPES OF SEQUENCE BOUNDARY OF THE QIANGTANG BASIN IN NORTHERN TIBET