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1.
上扬子克拉通南缘中泥盆统--石炭系高频层序及复合海平面变化 总被引:9,自引:0,他引:9
上扬子克拉通南缘中泥盆统-石炭系地层高频层序可以划分为三个级别,并与层序地层学术语可以对比:六级层序-韵律层;五级层序-准层序;四级层序-准层序组。不同级别高频层序的形成受米兰柯维奇驱动力引起的具不同周期和频率的复合海平面变化控制。克拉通边缘沉积环境中,低频海平面变化的上升阶段形成以淹没节拍为主的高频层序,而在停滞至下降阶段形成以暴露节拍为主的高频层序。所以,通过对不同特征的高频层序及垂向叠加的分析,可以求解低频海平面的变化。 相似文献
2.
上扬子克拉通南缘中泥盆统-石炭系高频层序及复合海平面变化 总被引:4,自引:0,他引:4
上扬子克拉通南缘中泥盆统—石炭系地层高频层序可以划分为三个级别 ,并与层序地层学术语可以对比 :六级层序—韵律层 ;五级层序—准层序 ;四级层序—准层序组。不同级别高频层序的形成受米兰柯维奇驱动力引起的具不同周期和频率的复合海平面变化控制。克拉通边缘沉积环境中 ,低频海平面变化的上升阶段形成以淹没节拍为主的高频层序 ,而在停滞至下降阶段形成以暴露节拍为主的高频层序。所以 ,通过对不同特征的高频层序及垂向叠加的分析 ,可以求解低频海平面的变化 相似文献
3.
尼日尔三角洲深水区层序地层及地震相研究 总被引:5,自引:1,他引:4
中新世至上新世,研究区发育深海平原和陆坡坡脚沉积。缺少反映海平面变化的上超特征和削截现象,很难利用地震反射终止类型(上超、顶超、削截)进行层序界面识别。文中利用深水区沉积旋回的地震相特征差异进行层序界面识别,并建立了研究区层序演化模式:低位体系域发育重力流沉积(块状搬运复合体、浊积扇)———海侵高位体系域深海泥质发育。以层序为格架进行地震相和沉积相在时间和空间分布特征分析。研究区识别出两类叠加地 震相样式:杂乱反射块状搬运复合体———丘形水道—堤岸复合体(浊积扇)———平行反射深海泥质沉积;丘形水道—堤岸复合体(浊积扇)———平行反射深海泥质沉积。 相似文献
4.
华北地台中寒武统张夏组上部高频层序研究 总被引:8,自引:1,他引:7
根据华北地台东部寒武系露头层序地层研究,将张夏组划分为两个正层序,其中上部正层序(530-525MaB.P.,三叶虫带Amphoton-Taitzuia带至Damesela带)由4个亚层序和17-23个小层序组成,其中正层序和亚层序具有高分辨率区域地层对比意义。每一级层序均表现为向上变浅和变粗进积型序列,底部常以间断-加深面或洪泛面为界。该时期的海平面变化具有高频振荡特点,构成一个三级复合海平面变化旋回。由不同级别层序所反映的海平面变化旋回可以分别与天文周期的奥特周期(2—5Ma)、米兰科维奇长周期(0.1—0.4Ma)和米兰科维奇短周期(0.02—0.04Ma)相对比。据层序地层和相序及相模式的研究,识别出6种类型的小层序,陆棚盆地至上缓坡显示出由A—F类型的规律性变化。 相似文献
5.
扬子板块石炭纪沉积层序及其全球性对比研究 总被引:8,自引:3,他引:8
通过对石炭纪扬子板块内部、扬子板块与华北板块及扬子板块与欧美板块之间的不同级别沉积层序对比研究,编制了扬子板块、华北板块和欧美板块石炭纪的海平面变化曲线。在扬子板块内部,上、下扬子区2级沉积层序可以进行对比,但下扬子区海进和海岸上超滞后于上扬子区,由于资料的限制,3级沉积层序的对比还有困难;华北板块Fusulina-Fusulinela带内的一个3级沉积层序和Triticites-Peudoschwagerina带内的四个3级沉积层序,可以和扬子板块同期的3级沉积层序对比;扬子板块和北美中大陆不仅3级沉积层序可以对比,而且在晚石炭世Gzhelian期4级沉积层序也可以进行对比,但由于它们大地构造背景的差异,导致沉积层序组成内容的不同。上述对比结果被认为是冰川型全球海平面变化所形成全球沉积记录同时性的证据。并以冰期与非冰期、联合古陆形成前后等方面对相同板块内和不同板块间沉积层序的数量和级别的异同原因进行了探讨,认为石炭纪冈瓦纳大陆冰川消长是控制全球海平面变化的主要因素,因此,沉积层序应具全球同时性和可对比性,但局部沉积条件差异也将影响沉积层序组成。 相似文献
6.
黔南独山石炭系层序地层及麦粒蜓带冰… 总被引:17,自引:2,他引:17
应用露头层序地层学原理和方法,对黔南独山地区碳酸盐岩为主的石炭系著名剖面进行了重新研究,识别出10个三级层序,其中岩关阶2个,大塘阶3个,威宁阶2个,马平组3个,大部分可以在台地和斜坡带追踪对比,在晚石炭世Triticites(Tr)带内识别出17个副层序和相应的海平面变化旋回,可以与北美中大陆同期17个四级层序和相应的海侵-海退旋回对比,黔南和北美中大陆之间存在相同的冰川型全球海平面变化和不同的 相似文献
7.
前陆盆地层序地层学研究中的几个问题 总被引:11,自引:2,他引:9
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。 相似文献
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鄂尔多斯盆地中部马五1亚段高分辨率层序地层格架中风化成岩模式和储层特征 总被引:7,自引:0,他引:7
以层序地层学理论为指导,研究了鄂尔多斯盆地中部奥陶系风化壳储层的层序地层特征,建立了马五1亚段的高分辨率层序地层格架,在其内识别出了4 个准层序;通过建立海平面变化与风化成岩( 岩溶) 作用的关系模式,从成因上阐明了层间岩溶和后期高级别的风化成岩( 岩熔) 作用的发生过程和控制因素,揭示了在碳酸盐岩高分辨率层序地层格架中,不同级别的海平面变化周期控制着不同级别的沉积层序和风化成岩( 岩溶) 作用;分析了准层序与储层物性的关系,认为在鄂尔多斯盆地中部奥陶系风化壳储层中,准层序界面控制着层间岩溶的发育,是影响马五1 亚段风化壳储层性质的主要因素。 相似文献
10.
运用层序地层学原理和工作方法,对豫西震旦系进行了详细地研究,识别出三个I类层序,并建立起了各层序的等时格架,系统地研究了地层沉积相带在层序格架中的分布规律和成因联系。认为相对产面变化是我层序,体系域形成的主导因素。以相对海平面升降作为等时周期,不同成因背景下的沉积物就具有等时性。可以对比。同时,对相应的海平面变化曲线的绘制方法进行了尝试。 相似文献
11.
Wang Xunlian Department of Geology Mineral Resources China University of Geosciences Beijing 《中国地质大学学报(英文版)》1999,10(2)
Sequencestratigraphydealswiththecyclicityinsedi-mentaryrocksandregardsatleastsomeofthecyclicityasglobalinextent.Infact,sedime... 相似文献
12.
Mohammad Ali Kavoosi 《Geological Journal》2016,51(4):523-544
Upper Callovian to Tithonian (late Jurassic) sediments represent an important hydrocarbon reservoir in the Kopet‐Dagh Basin, NE Iran. These deposits consist mainly of limestone, dolostone, and calcareous mudstone with subordinate siliciclastic interbeds. Detailed field surveys, lithofacies and facies analyses at three outcrop sections were used to investigate the depositional environments and sequence stratigraphy of the Middle to Upper Jurassic interval in the central and western areas of the basin. Vertical and lateral facies changes, sedimentary fabrics and structures, and geometry of carbonate bodies resulted in recognition of various carbonate facies related to tidal flats, back‐barrier lagoon, shelf‐margin/shelf‐margin reef, slope and deep‐marine facies belts. These facies were accompanied by interbedded beach and deep marine siliciclastic petrofacies. Field surveys, facies analysis, parasequences stacking patterns, discontinuity surfaces, and geometries coupled with relative depth variation, led to the recognition of six third‐order depositional sequences. The depositional history of the study areas can be divided into two main phases. These indicate platform evolution from a rimmed‐shelf to a carbonate ramp during the late Callovian–Oxfordian and Kimmeridgian–Tithonian intervals, respectively. Significant lateral and vertical facies and thickness changes, and results obtained from regional correlation of the depositional sequences, can be attributed to the combined effect of antecedent topography and differential subsidence related to local tectonics. Moreover, sea‐level changes must be regarded as a major factor during the late Callovian–Tithonian interval. Copyright © 2015 John Wiley & Sons, Ltd. 相似文献
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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. 相似文献
14.
High-frequency sequences and their stacking patterns: sequence-stratigraphic evidence of high-frequency eustatic cycles 总被引:18,自引:0,他引:18
A hierarchy of interpreted eustatic cyclicity in siliciclastic sedimentary rocks has a pattern of superposed cycles with frequencies in the ranges of 9–10 m.y., 1–2 m.y., 0.1–0.2 m.y., and 0.01–0.02 m.y. (second- through fifth-order cyclicity, respectively). Stratigraphic units displaying this cyclicity include composite sequences, sequences, and parasequences. On the Exxon global cycle chart, fundamental third-order cycles (1–2 m.y. average duration) stack into related groups (second-order cycles: 9–10 m.y. duration). A much larger pattern (about 200 m.y.) is interpreted as tectonically controlled eustasy probably related to sea-floor spreading rates.
One and probably two higher orders of cyclicity (fourth-order: 0.1–0.2 m.y.; and fifth-order: 0.01–0.02 m.y.) are now observed in work with well logs, cores, and outcrops in areas of very rapid deposition. These frequencies are in the range of Milankovitch cycles, and may represent part of the Milankovitch hierarchy which has been widely interpreted for cyclical units in carbonate rocks.
High-frequency (fourth-order) sequences, which form at a 0.1–0.2 m.y. cyclicity, have all the stratal attributes of conventional sequences, including constituent parasequences and systems tracts, and play a dominant role controling reservoir, source, and sealing rock distribution. A consistent hierarchy of stratigraphy is observed. Parasequences (probable fifth-order cyclicity) stack into sets to form systems tracts in fourth-order sequences. Groups (sets) of fourth-order sequences are deposited between major third-order boundaries within third-order composite sequences. Sequences in these sets stack in prograding and backstepping patterns to form third-order lowstand, transgressive, and highstand sequence sets.
Third-order sequence boundaries are marked by greater basinward shifts in facies, by larger more widespread incised valleys, and by more extensive onlap than are fourth-order sequence boundaries. Third-order condensed sections commonly are widespread, faunally rich, and widely correlated biozone and mapping markers. Fourth-order sequence analysis helps to understand reservoir, source, and seal distribution at the play and prospect scale. An example from the Gulf of Mexico is discussed. 相似文献
15.
Reef geometries, erosion surfaces and high-frequency sea-level changes, upper Miocene Reef Complex, Mallorca, Spain 总被引:5,自引:0,他引:5
LUIS POMAR 《Sedimentology》1991,38(2):243-269
The upper Miocene Reef Complex of Mallorca is a 20-km prograding unit which crops out in sea cliffs along the southern side of the island. These vertical and exceptionally clean outcrops permit: (i) identification of different facies (lagoon, reef front, reef slope and open platform) and their geometries and boundaries at different scales, ranging from metre to kilometre, and (ii) construction of a 6-km-long high-resolution cross-section in the direction of reef progradation. This cross-section shows vertical shifts of the reefal facies and erosion surfaces linked to a general progradational pattern that defines the accretional units. Four hierarchical orders of magnitude (1-M to 4-M) of accretional units are identified by consideration of the vertical facies shifts and by which erosion surfaces are truncated by other erosion surfaces. All these orders show similar patterns: horizontal beds of lagoonal facies in the upper part (landward), reefal and slope facies with sigmoidal bedding in the central part, and open-platform facies with subhorizontal bedding in the lower part (basinwards). The boundaries are erosion surfaces, horizontal over the lagoon facies, dipping basinwards over the reef-front facies and connecting basinwards with their correlative conformities over the reef-slope and open-platform facies. The four orders of accretional units are interpreted in terms of four (1-M to 4-M) hierarchies of sea-level cycles because (i) there is a close relation between the coral growth and the sea surface, (ii) there are vertical shifts in the reefal facies and their relation to the erosion surfaces, and (iii) there was very little tectonic subsidence in the study area during the late Miocene. Additionally, all these units can be described in terms of their position relative to the sea-level cycle: (i) the reefs prograde on the open-platform sediments during low stands of sea-level; (ii) aggradation of the lagoon, reef and open-platform facies dominates during sea-level rises, and the lagoonal beds onlap landwards upon the previous erosion surface; (iii) reefal progradation occurs during high stands of sea-level; and (iv) the 2-M sea-level fall produces an off-lapping reef and there is progradation with downward shifts of the reefal facies and erosion landward on the emerged (older) reefal units (A-erosion surfaces); the 3-M and 4-M sea-level falls produce only erosion (B-and C-erosion surfaces). Although precise age data do not exist at present, some speculations upon the frequency of these Miocene relative sea-level cycles can be made by comparisons with Pleistocene cyclicity. There is a good correlation between the Miocene 2-M cycles and the 100-ka Pleistocene cycles. Consequently, the 1-M cycles can be assigned to a fourth order in relation to previously proposed global cycles and the 2-M to fifth-order cycles. All these accretional units could be defined as ‘sequences’, according to the definition as commonly used in sequence stratigraphy. However, they represent higher than third-order sea-level cycles, but are not parasequences. The term subsequence, therefore, is suggested to define ‘a part of a sequence bounded by erosion surfaces (mostly subaerial) and their correlative conformities basinwards'. A hierarchy of subsequences can be established. 相似文献
16.
High-frequency cycles in Upper Aptian carbonates have been studied on the carbonate ramp of Organyà (southeastern Pyrenees).
The depositional area comprises a shallow marine to deeper marine transect. A detailed facies model is developed subdividing
the transect into an inner ramp area (above fairweather wave base), a mid-ramp area (between fairweather wave base and storm
wave base) and an outer ramp area (below storm wave base).
Based on microfacies analysis a cyclostratigraphic and sequence stratigraphic interpretation is established. Variations of
the sedimentary patterns within different sections of the homoclinal ramp are due mainly to sea level changes. Sea level changes
of third and fourth order are reflected by the shifting of the shallow subtidal facies belts up and down the ramp. The study
of fifth-order sea level changes is based on statistical methods (quantitative facies analysis and principal component analysis).
The ratio of the fourth- and fifth-order cycles is very similar to the well-known ratio of the eccentricity (100 ka) and the
precession (18.6/22.5 ka). The absolute age values derived from the cyclostratigraphy fit into the biostratigraphic framework.
Thus, a global eustatic control is assumed to be responsible for the cycles of higher frequency. The lower frequency third-order
sequences, however, were considerably influenced by local tectonic processes. 相似文献
17.
泌阳断陷下第三系核三上亚段层序地层学研究 总被引:4,自引:0,他引:4
根据陆相层序在地震剖面及电测曲线上的识别标志和在岩石矿物学方面的旋回性特征,采用沉积旋回分析技术及Fischer图解法,将泌阳断陷双河—赵凹地区下第三系核三段上亚段划分为3个陆相层序,其沉积体系呈现冲积扇—扇三角洲—湖相空间配置关系。在这3个陆相层序中共发育小层序组13个,其中可识别的小层序达50余个。针对研究区目的层段所划3个陆相层序发育的共同特点,在连井剖面层序地层对比的基础上,编制了研究区目的层段的陆相层序地层等时框架模式。 相似文献
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JOSÉ F. GARCÍA-HIDALGO JAVIER GIL MANVEL SEGURA CARMEN DOMÍNGUEZ† 《Sedimentology》2007,54(6):1245-1271
The Late Cenomanian–Mid Turonian succession in central Spain is composed of siliciclastic and carbonate rocks deposited in a variety of coastal and marine shelf environments (alluvial plain–estuarine, lagoon, shoreface, offshore‐hemipelagic and carbonate ramp). Three depositional sequences (third order) are recognized: the Atienza, Patones and El Molar sequences. The Patones sequence contains five fourth‐order parasequence sets, while a single parasequence set is recognized in the Atienza and El Molar sequences. Systems tracts can be recognized both in the sequences and parasequence sets. The lowstand systems tracts (only recognized for Atienza and Patones sequences) are related to erosion and sequence boundary formation. Transgressive systems tracts are related to marine transgression and shoreface retreat. The highstand systems tracts are related to shoreface extension and progradation, and to carbonate production and ramp progradation. Sequences are bounded by erosion or emergence surfaces, whose locations are supported by mineralogical analyses and suggest source area reactivation probably due to a fall in relative sea‐level. Transgressive surfaces are subordinate erosion and/or omission surfaces with a landward facies shift, interpreted as parasequence set boundaries. The co‐existence of siliciclastic and carbonate sediments and environments occurred as facies mixing or as distinct facies belts along the basin. Mixed facies of coastal areas are composed of detrital quartz and clays derived from the hinterland, and dolomite probably derived from bioclastic material. Siliciclastic flux to coastal areas is highly variable, the maximum flux postdates relative sea‐level falls. Carbonate production in these areas may be constant, but the final content is a function of changing inputs in terrigenous sediments and carbonate content diminishes through a dilution effect. Carbonate ramps were detached from the coastal system and separated by a fringe of offshore, fine‐grained muds and silts as distinct facies belts. The growth of carbonate ramp deposits was related to the highstand systems tracts of the fourth‐order parasequence sets. During the growth of these ramps, some sediment starvation occurred basinwards. Progradation and retrogradation of the different belts occur simultaneously, suggesting a sea‐level control on sedimentation. In the study area, the co‐existence of carbonate and siliciclastic facies belts depended on the superimposition of different orders of relative sea‐level cycles, and occurred mainly when the second‐order, third‐order and fourth‐order cycles showed highstand conditions. 相似文献