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1.
Sedimentary facies and sequence stratigraphy of the Asmari Formation at Chaman-Bolbol, Zagros Basin, Iran 总被引:1,自引:0,他引:1
Mahnaz Amirshahkarami Hossein Vaziri-Moghaddam Azizolah Taheri 《Journal of Asian Earth Sciences》2007,29(5-6):947-959
The Oligocene–Miocene Asmari Formation of the Zagros Basin is a thick sequence of shallow water carbonate. In the study area, it is subdivided into 14 microfacies that are distinguished on the basis of their depositional textures, petrographic analysis and fauna. Based on the paleoecology and lithology, four distinct depositional settings can be recognized: tidal flat, lagoon, barrier, and open marine. The Asmari Formation represents sedimentation on a carbonate ramp. In the inner ramp, the most abundant lithofacies are medium grained wackestone–packstone with imperforated foraminifera. The middle ramp is represented by packstone–grainstone to floatstone with a diverse assemblage of larger foraminifera with perforate wall, red algae, bryozoa, and echinoids. The outer ramp is dominated by argillaceous wackestone characterized by planktonic foraminifera and large and flat nummulitidae and lepidocyclinidae. Three third-order depositional sequences are recognized from deepening and shallowing trends in the depositional facies, changes in cycle stacking patterns, and sequence boundary features. 相似文献
2.
Facies, depositional environment and diagenetic processes of the early Mid-Miocene Jeribe Formation, Central and Southern Iraq 总被引:2,自引:1,他引:1
Moutaz A. Al-Dabbas Jassim A. Al-Jassim Yassin S. Al-Jwaini 《Arabian Journal of Geosciences》2013,6(12):4743-4754
The Jeribe Formation (Early Middle Miocene) in the central and southern Iraq consists mainly of shallow marine carbonates. Many microfacies have been identified: mudstone, wackestone, packstone, and grainstone with seven submicrofacies. Four major depositional cycles were determined. Microfacies developments and their distribution are controlled by cyclicity and relative sea level fluctuations. The Allochems in the Jeribe Limestone Formation are dominated by bioclasts. Peloids, ooids, and intraclasts are less abundant. The fossils are represented by benthonic forams and very rare planktonic forams. Calcite and dolomite are the predominant mineral components of Jeribe Formation. The carbonates of Jeribe have been affected by a variety of diagenetic processes such as compaction, dissolution, cementation, neomorphism, dolomitization, anhydritization, and silicification. By using the lithofacies association concepts, the depositional model of the Jeribe Formation environment was built. The Jeribe was deposited in open to restricted platforms which indicated lagoonal environment with warm and restricted-open circulation and the lower part (in well Hemrin-2) was deposited in foreslope environment. 相似文献
3.
Moutaz A. Al-Dabbas Jassim A. Jassim Amanj I. Qaradaghi 《Arabian Journal of Geosciences》2012,5(2):297-312
Nineteen subsurface sections and a large number of thin sections of the Mauddud limestone (age Albian?CEarly Cenomanian) were studied to unravel the depositional facies and environments. The allochems in the Mauddud Formation are dominated by bioclasts (reach 23%) and peloids (reach 60%), whereas intraclasts are less abundant (reach 2.3%). The sedimentary microfacies of the Mauddud Formation includes lime mudstone, wackestone, wackestone?Cpackstone, packstone, packstone?Cgrainstone, in addition to dolostone lithofacies and green shale lithofacies. These microfacies have been deposited in shallow warm marine environment of varying salinities and energy levels. Cementation, neomorphism, dolomitization, compaction, and dissolution are observed affecting variably both ground mass and particles. The formation displays various extents of dolomitization and is cemented by calcite and dolomite. Dolomitization increases toward the north of the study area and exhibits different textures. Similarly cementation shows a variety of textures. In addition, authigenic minerals, such as glauconite and pyrite, are scattered within the groundmass and along solution surfaces. The formation has gradational contact with the underlying Nahr Umr Formation but is unconformably overlain by the Ahmadi Formation, despite local conformity. Thus, the vertical bioclast analysis indicates that the Mauddud Formation is characterized by four major depositional cycles, which control the distribution of reservoir quality as well as the patterns of calcite and dolomite, cement distribution. Petrographical study shows that the fossil represents the main Allchem, Peloids, whereas intraclasts come second in abundance. Calcite (more than 50%) and dolomite (as diagenetic products, range between 20% and 50%) are the predominant mineral components of Mauddud Formation. Fossils were studied as an environmental, age, and facial boundary indicators. Five major depositional microfacies are recognized. These depositional microfacies have been subdivided according to their primary and diagenetic constituents into ten submicrofacies. The determined four major depositional cycles were representing normal sequential regression from base upward. The lateral analysis shows the same regressive cycle and by using the lithofacies association concepts to build the depositional model of the Mauddud Formation environment. 相似文献
4.
Isolated, high relief carbonate platforms developed in the intracratonic basin of east-central Mexico during Albian-Cenomanian time. Relief on the platforms was of the order of 1000 m and slopes were as steep as 20–43°. Basin-margin debris aprons adjacent to the platforms comprise the Tamabra Formation. In the Sierra Madre Oriental, at the eastern margin of the Valles-San Luis Potosi Platform, an exceptionally thick (1380m) progradational basin to platform sequence of the Tamabra Formation can be divided into six lithological units. Basinal carbonate deposition that preceded deposition of the Tamabra Formation was emphatically punctuated by an allochthonous reef block 1 km long by 0·5 km wide with a stratigraphic thickness of 95 m. It is encased in Tamabra Formation unit A, approximately 360 m of peloidal-skeletal wackestone and lithoclastic-skeletal packstone that includes some graded beds. Unit B is 73 m of massive dolomite with sparse skeletal fragments and intraclasts. Unit C, 114m thick, consists of structureless skeletal wackestone passing upward into graded skeletal packstone. Interlaminated lime mudstone and fine grained bioclastic packstone with prominent horizontal burrows are interspersed near the top. Unit D is 126 m of breccia with finely interbedded skeletal grainstone and burrowed or laminated mudstone. The breccias contain a spectrum of platform-derived lithoclasts and basinal intraclasts, up to 10 m in size. The breccias are typically grain supported (rudstone) with a matrix of lightly to completely dolomitized mudstone or skeletal debris. Beds are up to several metres thick. Unit E is 206 m of massive, sucrosic dolomite that replaced breccias. Unit F is approximately 500 m of thick bedded to massive skeletal packstone with abundant rudists and a few mudstone intraclasts. Metre scale laminated lime mudstone beds are interspersed. The section is capped by El Abra Formation platform margin limestone, consisting of massive beds of caprinid packstone and grainstone with many whole valves. Depositional processes within this sequence shift from basinal pelagic or peri-platform sedimentation to distal, platform-derived, muddy turbidity currents with a large slump block (Unit A); through more proximal (coarser and cleaner) turbidity currents (Unit B?, C); to debris flows incorporating platform margin and slope debris (Units D, E). Finally, a talus of coarse, reef-derived bioclasts (Unit F) accumulated as the platform margin prograded over the slope sequence. Interspersed basinal deposits evolved gradually from largely pelagic to include influxes of dilute turbidity currents. Units containing turbidites with platform-derived bioclasts reflect flooding of the adjacent platform. Breccia blocks and lithoclasts were probably generated by erosion and collapse of the platform during lowstands. Laminated, black, pelagic carbonates, locally cherty, are interbedded with both breccias and turbidites. At least those interbedded with turbidites may have been deposited within an expanded mid-water oxygen minimum zone during relative highstands of sea level. They are in part coeval with mid-Cretaceous black shales of the Atlantic Ocean. 相似文献
5.
Afrah H. Saleh 《Arabian Journal of Geosciences》2014,7(8):3175-3190
The Yamama Formation is the main Lower Cretaceous (late Berriasian–Valangenian) carbonate reservoir in southern Iraq. Petrographic study from thin-section examination shows that the skeletal grains included calcareous algae from both red and green algae. Red algae is concentrated in the upper part of the Formation, and the most important of this algae species is Permocalculus ssp. Green algae is less common, and its concentration is in the middle part of the Formation. The most species found in the Yamama Formation is dasycladeans, and both small and large species of benthonic foraminifera such as Nautiloculina, Textularia, Trocholina, Pseudocyclammina, and Everticyclammina are also present. The non-skeleton grains included oolites, pellets, and micrite. Six cyclic type microfacies have been recognized for Yamama Formation in Ratawi-3 (Rt-3) and Ratawi-4 (Rt-4) Wells, namely peloidal packstone–grainstone, algal wackestone–packstone, oolitic–peloidal grainstone, bioclastic wackestone–packstone, foraminiferal wackestone, and mudstone microfacies. The latter has been divided into two submicrofacies: argillaceous lime mudstone and fossiliferous lime mudstone. The lateral extension of these microfacies has been identified by integrating the thin-section data and well logs’ character variations with similar characteristic for microfacies. The Yamama Formation was affected by five diagenetic processes, which are micritization, cementation, recrystallization, silicification, and stylolites. The Yamama Formation was deposited during a regressive period within the outer ramp, shoal, and inner ramp setting. 相似文献
6.
Outcrop and microscopic studies have been applied in this research paper in order to find out the Asmari Formation depositional sequences in the Shajabil Anticline section located at the north of the Izeh Zone,Zagros Basin,Iran.Five depositional sequences were identified based on 11 facies types (bioclast Nummulitidae Lepidocyclinidae packstone,bioclast perforate foraminifera Nephrolepidina Miogypsinoides wackestone-packstone,bioclast perforate foraminifera Corallinacea wackestone-packstone,bioclast echinoid Neorotalia Brachiopoda wackestone-packstone,coral floatstone-rudstone,bioclast Corallinacea imperforate foraminifera wackestone-packstone,bioclast imperforate foraminifera Archaias wackestone-packstone,bioclast imperforate foraminifera Dendritina wackestone-packstone-grainstone,bioclast imperforate foraminifera Borelis wackestonepackstone and very fine sandy mudstone) corresponding to the tidal flat,restricted and semirestricted lagoon and open marine environments of an inner and middle shelf areas.Well-exposed outcrop horizons of Thalassinoides at the study section are a favorable tool for the regional outcrop sequence stratigraphy.Thalassinoides is considered as an outcrop key-bed for recognition of the Rupelian-Chattian maximum flooding depositional sequence.Coral remnants (small colonies) in outcrop exposures also are associated with the HST depositional sequence (Chattian) for the Asmari Formation.The most important achievement of this research is use of associated maximum flooding surfaces (Pg30,Pg40,Pg50,Ngl0 and Ng20) in the Arabian plate.These maximum flooding surfaces could be recorded as an isochrones surface. 相似文献
7.
塔中地区晚奥陶世碳酸盐台缘与台内沉积差异--定性和定量的碳酸盐岩微相综合分析 总被引:2,自引:2,他引:0
为揭示塔中地区东部的晚奥陶世镶边型碳酸盐台地边缘与台地内部的沉积差异,利用钻井岩芯及薄片资料,对良里塔格组开展了定性的和定量的碳酸盐岩微相分析研究。研究表明,台缘-台内沉积区发育9种微相类型(MF1~MF9),不同颗粒岩类微相所代表的几种颗粒滩具有典型差别的粒度累积频率曲线样式。台地边缘主要发育各种高能颗粒滩的微相组合(MF1~MF4),与台缘生物礁构成礁滩复合体;台地内部主要发育代表中-低能的潮坪-潟湖沉积的微相组合(MF5~MF9)。结合定量的粒度分析分析认为生屑砂屑颗粒灰岩微相(MF1)、生屑砾屑灰岩微相(MF2)和鲕粒颗粒灰岩微相(MF3)是冲流带(前滨)环境的产物,分别代表着台地边缘生屑滩、鲕粒滩和礁前砾屑滩沉积;球粒颗粒灰岩微相(MF5)为位于受障壁的台地内部、中等能量波浪控制的球粒滩;棘屑泥粒灰岩-漂浮岩微相(MF4)发育于台缘礁后的中-高能生屑滩。 相似文献
8.
The Jubaila Formation (Upper Jurassic) in central Saudi Arabia has been divided into lower, middle, and upper parts purely on lithologic grounds. Each part consists of a major lower unit of lime mudstone and a minor upper unit of grainstone. This persistent change in the limestone facies is interpreted as a reflection of repeated shoaling up in the depositional shelf environment. It is a normal marine carbonate sequence that varies in thickness from 85 to 126 m. In the Hanifa Formation, the lowermost brown ledges in the section comprise a series of coarsening upward sequences which generally terminate in a fossiliferous/peloidal packstone and grainstone and subordinately lime mudstone facies. The middle slope member is yellow, blocky weathered shale and marl. Above this slope member are several thick beds of brown-coated fossiliferous wackestone, packstone, and grainstone with the association of lime mudstone in certain levels. These are fairly resistant ledges due to the occurrence of stromatoporoids. Dedolomitization occurs in the Jubaila Formation in various textural forms which include composite calcite rhombohedra, zonal dedolomitization, regeneration of predolomitization fabric of the limestone, and coarsely crystalline calcite mosaics with or without ferric oxide rhombic zones. Rhombohedral pores commonly occur in intimate association with dolomite, possibly resulting from the leaching of calcitized dolomite rhombohedra. The regional dedolomitization was most likely brought about by calcium sulfate solutions reacting with dolomites. The source of sulfate solutions is the dissolved anhydrite deposits of the Arab–Hith Formations, sometime before their erosion, and it takes place at or near an exposed surface. The Hanifa Formation shows various diagenetic features. These include dolomitization, dedolomitization, micritization, cementation, and recrystallization. Most of the examined samples of the Hanifa carbonates are dolomitized and subsequently dedolomitized as evidenced by the presence of iron-coated dolomite rhombs partially or completely calcitized. Dolomite also occurs in the lime mudstone, wackestone, packstone, and grainstone facies, while leaching of wackestone and packstone and dedolomitization of dolomite and dolomitic limestone followed by recrystallization are common processes. 相似文献
9.
针对中- 晚三叠世扬子台地的淹没事件,分析了黔西南贞丰挽澜中- 上三叠统竹杆坡组的微相,并讨论了其沉积环境
演变。采用Flügel 标准微相的判别方法共识别出九种微相,包括:纹层状粘结灰岩、微晶藻球粒灰岩、泥晶灰岩、含生物
碎屑泥晶灰岩、棘皮泥晶灰岩、亮晶砂屑鲕粒生物碎屑灰岩、藻团块生物碎屑泥晶灰岩、含生物碎屑泥晶灰岩-P 和泥晶灰
岩-P。九种微相的有序组合和分布位置显示它们形成于快速的潮坪-台地边缘转变过程和漫长的深水陆棚及盆地环境。海
平面变化分析显示,黔西南中- 晚三叠世竹杆坡组沉积期的海平面变化不同于扬子台地主体,无论是二级旋回还是三级旋
回都响应于全球海平面变化。 相似文献
10.
The Lower Ordovician La Silla Formation of the Precordillera of west‐central Argentina is part of the west‐facing early Palaeozoic, tropical carbonate platform succession that comprises the core of the Cuyania terrane. Up to 360 m thick, it is exposed in several thrust sheets over a distance of some 250 km along and across depositional strike over a palinspastically unrestored distance of about 35 km. La Silla Formation is a strikingly pure limestone with subordinate finely crystalline dolomite and rare chert. It accumulated on a more or less uniformly subsiding passive margin. Copious precipitation of microcrystalline calcite, probably influenced by microbial activity to varying degrees, led to the generation of peloids, ooids and aggregates of these grains, as well as small amounts of lime mud, intraclasts, stromatolites and thrombolites. Rare bioclasts are limited mostly to scattered gastropods and trilobite sclerites; bioturbation is present locally. The array of carbonate rock types is grouped into eight recurring lithofacies, in order of decreasing abundance: (i) peloidal grainstone; (ii) laminated dolostone; (iii) intraclastic rudstone; (iv) microbial laminite; (v) peloidal packstone; (vi) ooidal grainstone; (vii) thrombolite boundstone; and (viii) mudstone. These facies represent sediments that formed solely in a shallow subtidal marine environment, with no evidence of restricted conditions, hypersalinity or subaerial exposure. No events of eustatic sea‐level change are recorded. By far the dominant facies is grainstone composed of well‐sorted, fine sand‐sized peloids and peloidal aggregates in homogeneous, tabular to gently undulating, medium to thick beds; cross‐lamination is scarce. Clusters of sub‐metre‐sized microbial patch reefs developed sporadically. The shallow platform is envisaged to have been covered by extensive peloidal sand flats and low‐relief banks, and little lime mud was generated. The setting was probably microtidal and may not have been affected by strong trade winds. It was washed by frequent, relatively gentle wave action but without experiencing powerful storms. In the middle member, anomalous lenses of intraclastic rudstone and laminated dolostone occur as graded beds overlying sharply downcut scoured surfaces up to 20 cm deep; these are interpreted to indicate a phase when accretion was punctuated occasionally by tsunamis generated from rift‐faulting seaward of the platform margin. The remarkably uniform peloidal grainstone composition over a broad area shows that, given the appropriate combination of climate, environmental and ecological factors, large portions of some early Palaeozoic platforms were dominated by grainy sediment and remained under well‐agitated conditions within fair‐weather wave‐base, without distinct lateral facies differentiation or tidal‐flat aggradation. 相似文献
11.
Mohammed F. Al-Ghreri Amer S. Al-jibouri Ahmed Asker Al-Ahmed 《Arabian Journal of Geosciences》2014,7(7):2679-2687
The Euphrates formation is widely exposed in western Iraq near Al-Qaim area. It extends eastward parallel to the Euphrates River on both sides, crossing Anah, Hadetha, and Al-Baghdadi vicinities. Based on the benthic foraminiferal assemblages and microfacies features, 12 different microfacies types have been recognized into two Stratigraphic sections that are lime mudstone, wackestone, bioclastic wackestone, miliolids wackestone, alveolinids wackestone, packstone, bioclastic packstone, peloidal packstone, miliolids packstone, peneroplids packstone, rotaliids packstone, grainstone, peloidal grainstone, oolitic grainstone, and miliolids grainstone. Accordingly, the depositional environments were recognized on the basis of microfacies identification and interpretation ranging from restricted marine, shoal, to open marine environments. The exposed Euphrates succession is represented by four fourth-order cycles (A, B, C, and D); they are mostly asymmetrical showing slightly lateral variation in thickness and symmetry. These cycles represent a succession episode of sea level rises and stillstands. The nature of these cycles reflects variation in the relative sea level resulted from eustatic and tectonic subsidence. Cycle A is underlain by SB1 of Sheik Alas formation in Al-Baghdadi section and by Anah formation in Wadi Hjar section. Cycle D is overlain by SB1 of Fatha formation in Al-Baghdadi section and by conformable contact of Nfayil formation in Wadi Hjar section. According to sequence development, the study area shows low rate of subsidence and the major controlling factor that affects eustatic sea level fluctuation. 相似文献
12.
The Neogene carbonate rocks have relatively small exposure relative to the siliciclastic and evaporite rocks in Rabigh and Ubhur areas, north Jeddah, Red Sea coastal plain of Saudi Arabia. The Miocene carbonates form small hills in both areas, which conformably overlie the siliciclastics, whereas the Pleistocene coral reefs form terraces facing the Red Sea in Rabigh area. The Neogene carbonates are represented by the following microfacies types: (1) dolomitic, oolitic, foraminiferal packstone; (2) sandy, dolomitic, intraclastic, foraminiferal packstone; (3) dolomitic and oolitic wackestone; (4) dolomitic, foraminiferal, intraclastic wackestone; (5) dolomitic mudstone; (6) coral boundstone; and (7) grainstone. The diagenetic processes affecting these carbonates are compaction, dissolution, aggrading neomorphism, and replacement that took place during deposition, shallow burial, and uplift. Pervasive dolomitization by the seepage reflux mechanism is responsible for the mimic replacement of the calcite of the original component of the limestone with dolomite. Sediments, biota, and lithofacies characteristics of the studied carbonate rocks of Rabigh and Ubhur areas indicate the presence of three facies zones; these are (1) FZ 5 platform margin reefs, (2) FZ 6 (platform margin sand shoals), and (3) FZ 7 platform interior-normal marine. The standard microfacies types are represented by (1) SMF 12, limestone with shell concentration; (2) SMF 15, oolitic wackestone and packstone; and (3) SMF 18, bioclastic grainstone and packstone with abundant benthic foraminifera. 相似文献
13.
伊拉克哈法亚油田白垩系Mishrif组碳酸盐岩孔隙结构及控制因素 总被引:1,自引:1,他引:0
伊拉克哈法亚油田Mishrif组碳酸盐岩储层孔隙结构类型的差异性及对其控制因素的认识是制约该类储层分类评价的一个关键问题。综合利用岩芯、铸体薄片、扫描电镜、常规物性、压汞分析等手段及统计分析方法对储层的主要孔隙类型、喉道类型、喉道分布特征进行了研究,确定了孔隙结构划分依据和方案,并划分出了中低孔超低渗细喉型、中低孔低渗细喉型、中高孔中低渗中细喉型、高孔中低渗细喉型、中高孔中低渗细喉型、中高孔中低渗中喉型六种孔隙结构类型,并通过毛管压力曲线的形态划分出了Ⅰ-Ⅴ五类线型;研究区主要发育开阔台地相,并划分出8种储集岩类型,分别是泥晶灰岩、生屑粒泥灰岩、生屑泥粒灰岩、砂屑生屑泥粒灰岩、生屑颗粒灰岩、砂屑生屑颗粒灰岩、介壳类漂浮岩和岩溶建造岩,其中岩溶建造岩储层具有较特殊的网络状孔隙结构。因此,可以认为哈法亚Mishrif组储层主要受早成岩期岩溶作用影响,其早成岩期溶蚀具有明显的相控特征,是孔隙结构差异性的主要控制因素,极大的改善了该套储层的物性。 相似文献
14.
重庆市万盛区中二叠统碳酸盐岩分布广泛,露头发育良好,发育有10种微相类型,即灰泥石灰岩、筵粒泥灰岩、球粒生物碎屑粒泥灰岩、生物碎屑内碎屑泥粒灰岩、荷叶藻泥粒灰岩、鲕粒内碎屑泥粒岩/颗粒岩、小有孔虫泥粒灰岩、生物碎屑泥粒灰岩、绿藻颗粒灰岩和生物碎屑颗粒灰岩。综合分析表明,研究区中二叠统形成于滨岸、局限台地和开阔台地环境,据此建立了沉积相模式。 相似文献
15.
Quantitative analysis of sediment composition was performed on a kilometre wide section of Upper Tithonian low relief (up to 70 m), gently inclined (3° to 15°), sigmoidal carbonate clinoforms (eastern Sardinia) to identify changes in sediment composition along the slope and across the studied succession. These changes may reflect modifications of the carbonate factory and of processes responsible for sediment transport. Point‐count analysis of carbonate microfacies, Q‐mode/R‐mode cluster analysis and Spearman’s rank provided a composition‐based classification of microfacies and highlighted relationships among sediment components. The studied clinoforms are mainly composed of non‐skeletal grains (70%), such as peloids and lithoclasts, together with micrite and cements and only a limited contribution from coated grains (2%). Among skeletal grains (28%), the greatest contribution derives from a coral–stromatoporoid–encruster reef that provided 15% of the components. Crinoids, brachiopods and other along‐slope thriving biota provided nearly 5% of the allochems, whilst fragments of molluscs (gastropods, bivalves and diceratids) from the backreef sourced another 2%. The contribution of platform interior biota is negligible (1%). The association of composition‐based facies varies along the slope. The upper slope beds consist of coral‐stromatoporoid grainstone to rudstone; the middle slope deposits are dominated by encruster‐lithoclast grainstone and packstone. At the lower slope, peloidal lithoclastic packstone as well as brachiopod–crinoidal wackestone prevail. Also the association of skeletal grains changes along the slope. The encruster–frame builder association typifies the upper slope whilst encrusters characterize the middle slope sediments. In the lower slope encrusters are equally represented as the brachiopod–crinoid association. Along‐slope compositional changes evidence a scarce downslope transport of frame builders and a progressive enrichment in along‐slope thriving biota. Quantitative analysis of microfacies allowed the sigmoidal clinoforms to be grouped into six sets. Each set gathers sigmoids with a similar sediment composition. Coated grains are dominant in the first set whilst they are lacking in the overlying sets reflecting a change in the carbonate factory. Other major compositional changes among the sets concern the relative amounts of peloids, micrite, frame builders (corals and stromatoporoids) and encrusters. The contribution of peloids varies inversely to that of cements and micrite as evidenced in the third and fifth sets which, respectively, record the highest occurrence of peloids or cement and micrite. Variations in the amount of frame builders and encrusters are instead non‐linear. High percentages of both frame builders and encrusters, as recorded in the second and fifth sets, are related to low amounts of peloids and lithoclasts that probably reflect episodes of reduced background sedimentation. This study demonstrates that quantitative analysis of carbonate microfacies represents a powerful tool that can improve the reconstruction of the stacking pattern in carbonate slope successions both in outcrop and in subsurface settings. 相似文献
16.
山东省长清县中寒武统张夏组的微相组分、微相类型及沉积相分析 总被引:1,自引:1,他引:0
山东省长清县中寒武统的张夏-崮山剖面为华北地区张夏组的正层型剖面,其岩石地层、生物地层研究都较为成熟.从碳酸盐岩微相的角度,对其微相组分、微相类型和沉积环境作了进一步研究.在张夏-崮山地区的张夏组碳酸盐岩中识别出了6种微相类型:异地生物碎屑泥粒灰岩、附枝藻黏结灰岩、具再搬运鲕粒的粒泥-泥粒灰岩、含介壳及完整底栖化石的泥粒-粒泥灰岩、放射状鲕粒泥粒-粒泥灰岩和同心圆状鲕粒颗粒灰岩.微相类型的垂向叠覆及野外露头观察指示了5种沉积相带,自下而上分别为:局限台地鲕粒滩相、开阔台地海相、台地边缘鲕粒滩相、台地边缘藻礁相及台地边缘滩前斜坡相,表明山东省长清县张夏组为典型的镶边型碳酸盐岩台地沉积. 相似文献
17.
云南永德鱼塘寨石炭-二叠系界线剖面的生物地层学及沉积环境 总被引:1,自引:0,他引:1
云南永德鱼塘寨石炭-二叠界线剖面沉积连续、化石丰富,可作为滇西地区的代表性剖面,自石洞寺组至草坝山头组底部灰岩可划分出16种主要的碳酸盐微相类型,分别形成于外陆架、中陆架和内陆架环境。 相似文献
18.
Gong Soo 《中国地质大学学报(英文版)》2000,11(2)
The petrography, the geochemistry and the burial history all constrain the origin and modification history of dolomites in an ancient periplatform carbonate slope deposit,the Machari Formation (late Miclclle to early Late Cambrian),Korea. The formation is mainly composed of rhythmic bedding. laminated to bedded lime mudstone alternating with argillaceous lime mudstone. The rhythmic bedding is a product of the deposition of offshore periplatform ooze and hemipelagic clay on a periplatform slope. This formation also shows minor and intermittent influx of other lithofacies including the bioclastic-peloidal packstone, peloidal wackestone, and intraclasts deposited as turbidites. Five types of dolomite occur in the Machari Formation, whose occurrence.texture and geochemistry provide an insight into origin and modification history. 相似文献
19.
Tidal-flat and shoal deposits of carbonate fades in the Qiziqiao Formation are widely distributed over the vast areas of Guangxi, Guangdong and Hunan provinces, constituting an important stratigraphic unit where strata-bound and stratiform ore deposits (galena-sphalerite-pyrite) are found. These types of ore deposit seem to have close relations to the tidal deposits. Recognition of tidal deposits is based upon rock fabric, texture, structure, fossil assemblage, and particular sedimentary cycle. The typical sequence of tidal-flat deposits consists mainly of three units:Amphipora limestone, laminated limestone and dolostone (from the bottom to the top). This sequence represents a complete process of sedimentation from low-tideflat through intertidal to high-tideflat or supratidal. The sequence of shoal deposits of carbonate facies consists chiefly of grainstone and algal oösparite. Two major types of tidal deposit (open and restricted marine facies) can be distinguished, with eleven microfacies as follows: 1) calcarenite (grainstone) with sparite (MF-1); 2) algal oösparite (MF-2); 3) oncolite (alga-, or stromatoporoid-encrusted grains) (MF-3); 4) bioclastic grainstone (biosparite) or rudstone with sparite (MF-4);5) Amphipora limestone (MF-5); 6) dark fossil-poor micrite (MF-6); 7) pelsparite or peloidal grainstone with sparite (MF-7); 8) laminated pellet mudstone-wackstone (MF-8); 9) micrite with onkoids (MF-9); 10) rudstone or floatstone (MF-10; and 11) bedded dolomite-gypsum-dolomite (MF-11). 相似文献
20.
Mishrif组碳酸盐岩储层是波斯湾盆地最主要的储集层之一,储层岩石类型主要为礁滩相生物礁灰岩、生屑灰岩和含生屑泥灰岩,储集空间主要为粒间(溶)孔、晶间(溶)孔、铸模孔、表生期组构选择性溶蚀孔洞和基质微孔。储层多呈层状展布,横向上连续,边界受沉积相带约束; 纵向上发育多套致密隔夹层,呈强非均质性。储层发育与保存主要受沉积作用、成岩作用和构造作用影响。碳酸盐岩缓坡背景下发育的生物礁和生屑滩空间分布受盆地基底古构造格局控制,是优质储层分布相带。相对海平面升降旋回控制相带迁移和成岩作用差异,导致优质孔渗层与致密隔夹层交互发育。构造圈闭发育与油气充注时间的耦合有效抑制压实作用和胶结作用对储层的破坏,是储层得以保存的有利因素。 相似文献