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1.
Alain Piqu Edgard Laville Grard Bignot Mamy Rabarimanana Catherine Thouin 《Journal of African Earth Sciences》1999,28(4):931-948
In the western part of Madagascar, the Morondava Basin shows the Malagasy Karoo series, made of Late Carboniferous-Mid-Permian (Sakoa), Late Permian-Mid-Triassic (Sakamena) and Late Triassic-Mid-Jurassic (Isalo) sequences. The sedimentary facies are mainly aerial and clastic in the series, and the marine conditions are fully established after Lower Jurassic times, when the strait between Africa and Madagascar was flooded.The Karoo basins where these series were deposited are mainly hemi-grabens. Their filling proceeded from west to east and from south to north. Distinction between the southern and northern part of the Morondava Basin suggests that development of the basin was controlled by old crustal weakness zones trending north-northwest-south-southeast and north-northeast-south-southwest. 相似文献
2.
The stratigraphy of the western Portugal on-shore Cretaceous record (western Iberian margin, Lusitanian Basin) is described, including formal units and a selection of informal units prevailing in the geological literature. This paper is a synthesis based on a review of previous works, but with an innovative emphasis on the interpretation of eustatic and tectonic controls. The sedimentary record is dominated by siliciclastics and comprises fluvial and deltaic coastal marine siliciclastic systems, as well as extensive deposits of shallow marine carbonate platforms, both open and rimmed. Several regional unconformities and transgressive/regressive cycles are identified and the allogenic controls interpreted, namely the geodynamic events along the boundaries of the Iberian plate. Above the Berriasian deposits belonging to the Upper Jurassic cycle, the five main unconformity-bounded units are: (1) upper Berriasian–lower Barremian, (2) upper Barremian–lower Aptian, (3) upper Aptian–uppermost Cenomanian, (4) mid lower Turonian–lower Campanian and (5) middle Campanian–Maastrichtian. These units show transgressive peaks in the lower Hauterivian, lower Aptian, base of the upper Cenomanian and mid lower Turonian. The general trend of the Lower Cretaceous reflects the transition from late rifting to passive margin, with the last break-up unconformity dated as late Aptian. The Lusitanian Basin achieved full infill by the Cenomanian, when a large carbonate platform extended far inland. The later deposits were preserved only in the northern sector and the accompanying unconformities reflect transpressive intraplate stresses generated in boundaries of the plate with Africa and Eurasia. With very low accommodation being created throughout the Late Cretaceous, fluvial deposits were dominant, including a few marine levels related with eustatic rises in the early Turonian, the Coniacian, the early Campanian and the Maastrichtian. 相似文献
3.
The research area concentrates in a part of the main Zagros fold and thrust belt in the Kurdistan region (Northern Iraq). From study tectono-stratigraphy we constrain the story of the basin evolution of Kurdistan during Cretaceous. However we mainly investigated the evolution of the pre-Subduction and Pre-collision periods, focusing on the relationship between tectonics and sedimentation. For this purposes we developed (1) a biostratigraphic approach using nannofossil analysis, (2) a fault tectonic analysis, and (3) a stratigraphic study. The Zagros fold belt in Kurdistan exhibits many lateral and vertical environmental and facies changes, especially during the Cretaceous times. During the Jurassic period the Kurdistan is occupied by the restricted Gotnia Basin. This basin disappeared and the Kurdistan area changed to open marine of a southwest Kermanshah Basin during the Cretaceous. During the Berriasian to Barremian the Kurdistan was covered by the carbonates of the Balambo and Sarmord formations. In the east and southeast the neritic Sarmord Formation gradationally and laterally passes to the basinal facies of the Balambo Formation. In the Aptian to Cenomanian period shallow massive reefal limestone of the Qamchuqa Formation deposited. The normal faulting that initiates during the Aptian is associated with an abrupt lateral change of the reefal Qamchuqa Formation to the Aptian-Cenomanian part of the Balambo Formation. During the Cenomanian-Early Turonian periods the graben formed in the Dokan Lake in eastern Kurdistan, where developed a deeper restricted environment (Dokan and Gulneri formations) surrounded by a shallow marine platform. During the Turonian the marine pelagic micritic cherty limestones of Kometan Formation covered northeast of Kurdistan, whereas in the Safeen, Shakrok and Harir anticlines the formation was totally, or partially, weathered during the Coniacian-Early Campanian period. The deposition during the Late Cretaceous is very heterogeneous with a gap in the Coniacian-Santonian times probably related to a non-deposition. Associated with extensive tectonics a basin developed during the Campanian with the deposition of shales, marls and marly limestones of the Shiranish Formation. The first appearance is the Kurdistan of the flysch facies of the Tanjero Formation was precisely dated of the Upper Campanian in northeastern Kurdistan. The Tanjero Formation conformably overlaying the Shiranish Formation and was deposited in the foredeep basin associated with the obduction of Tethyan ophiolites onto the Arabian Platform. The Early to Late Campanian period is a time of non-deposition in Central Kurdistan (Safeen, Shakrok and Harir anticlines). During the Late Campanian the Bekhme carbonate platform in the north disappeared when the marly limestones of the Shiranish Formation transgressed over the Bekmeh Platform. In the Aqra area the Maastrichtian Tanjero Formation laterally changed to the thick reefal sequence of the Aqra Formation that unconformably overlies by the Late Paleocene-Early Eocene lagoonal carbonate of the Khurmala Formation. The Campanian sedimentation is mainly controlled by NE- oriented normal faults forming Grabens in Dokan, Spilk and Soran areas. During the Maastrichtian in the extreme northeastern Kurdistan the NE-SW and NNW-SSE normal faults developed in the foredeep basin and originated horsts and grabens. 相似文献
4.
松辽盆地及周缘地区是白垩纪时期全球最大的陆地出露区,是开展陆相J/K界线研究的理想地区。但是,受制于盆内埋深大、盆缘露头出露不佳等原因,松辽盆地及周缘地区J/K界线发育区域及层段仍然存在较大争议。同时,对于陆相J/K界线划分与对比这样的重大疑难问题,其研究很难一步到位。总结一套影响广泛、区域对比性强的J/K界线区域对比框架性特征,可以有效聚焦目标区域和层段,为进一步的精细研究明确方向。系统梳理松辽盆地及周缘典型地区J/K界线上下地层中记录的区域构造背景、岩浆事件和生物宏观演化阶段可发现:(1)松辽盆地以西和以南地区晚侏罗世为块体碰撞后陆壳加厚坍塌或拆沉的伸展环境,早白垩世为推覆陆壳加厚坍塌或拆沉的伸展环境;松辽盆地晚侏罗世为碰撞后持续造山环境,早白垩世为双侧活动陆缘影响下的区域性伸展-裂陷环境;松辽盆地以东地区晚侏罗世—早白垩世可能为走滑构造背景。(2)松辽盆地及周缘地区晚侏罗世—早白垩世生物演化阶段表现为晚侏罗世燕辽生物群的衰落和白垩纪热河生物群的兴起,其中晚侏罗世孢粉组合以裸子植物花粉占绝对优势、高Classopollis含量为特征,早白垩世则以松柏类两气囊花粉占绝对优势、低Classopollis含量为特征。(3)冀北—辽西地区的土城子组、黑龙江东部的东安镇组和东荣组应是J/K界线进一步工作的重点层段,大兴安岭地区的满克头鄂博组、松辽盆地常家围子断陷及其以西至大兴安岭局部地区可以尝试开展J/K界线研究工作。 相似文献
5.
通过对准噶尔盆地南缘侏罗系5条剖面的沉积特征对比,结合钻井资料和地震资料,确定了准噶尔盆地南缘侏罗纪盆地边界、沉积相演化及盆地格局。头屯河剖面和后峡剖面的沉积相对比及古流向测量表明二者在早、中侏罗世形成于同一沉积体系。在早、中侏罗世,沉积相逐渐从以辫状河-三角洲-湖泊相为主过渡到以河流相-湖泊相为主,沉积水体逐渐变浅;其中三工河组沉积时期盆地沉积范围达到最大,西山窑组沼泽相发育,车排子-莫索湾凸起自西山窑组沉积时期开始形成;早、中侏罗世的盆地边界至少位于后峡以南附近,此时不存在地理分割明显的天山山脉。晚侏罗世-早白垩世早期,沉积相从辫状河-滨浅湖相为主迅速演变为以辫状河-冲积扇相为主。在此期间盆地边界明显向北迁移,天山山脉明显隆升并造就天山南北沉积环境的巨大差异,博格达山构成盆地南缘的又一重要物源体系。 相似文献
6.
The early and late Frasnian, Barremian-Aptian, Cenomanian, early Santonian, early Campanian, and Oligocene-Miocene epochs
of the formation of various types of zirconium-titanium placers are distinguished in the Voronezh Anteclise. The factors of
their formation are considered, and a forecast of prospecting has been made. Lower Frasnian sedimentary rocks occur in the
southeast, where the placers are related to the ilmenite-bearing volcanosedimentary rocks of the Yastrebovo Sequence. The
upper Frasnian productive quartz sand of the Petino Sequence occurs in the central part of the Voronezh Anteclise. The Barremian-Aptian
productive quartz sand and kaolinite clay occur in the northern and northeastern parts of the anteclise (Ryazan and Lipetsk
oblasts). The placers formed in the Cenomanian are known in the Tambov oblast in the northeast of the Voronezh Anteclise and
are related to phosphate-bearing glauconite-quartz sand. The early Campanian phosphorite-glauconite-quartz formation is widespread
in the northwest of the Voronezh Anteclise at the junction with the northeastern wall of the Dnieper-Donets Basin (Bryansk
oblast). The Oligocene-Miocene epoch was characterized by quartz sands abundant in the northwestern and south-western areas.
The formation of zirconium-titanium placers is controlled by structural-tectonic, facies, volcanic, paleogeographic, stratigraphic,
and evolutional factors. The indispensable condition for heavy mineral concentration is existence of positive forms of underwater
topography. These are mostly structural elements of the third and fourth orders on the slopes of the Voronezh Anteclise at
the boundaries of the adjacent negative structures. As concerns the facies factor, the occurrence of coastal and shallow-water
marine facies with alternating and medium hydrodynamic activity and predominance of sand fractions 0.25–0.05 mm are criteria
of elevated concentration of heavy minerals in sand. One of the conditions providing concentration of heavy minerals is a
multiple rewashing of sands close to a relatively stable shoreline. The volcanic factor is determinant for the lower Frasnian
marine placers fed by volcanic sources. The Cretaceous and Paleogene zirconium-titanium placers were formed owing to scouring
of the older Paleozoic and Mesozoic sedimentary rocks of the Voronezh Anteclise, as well as the Baltic Shield, Moscow Syneclise,
and the Volga-Ural Anteclise. The age of placers was estimated with accuracy up to substages (lower Aptian, lower Santonian,
lower Campanian). The evolution factor is expressed in variation of localization and composition of placers in time and space.
The forecast of potentially ore-bearing areas is based on optimal combinations of favorable factors. 相似文献
7.
Low-temperature thermochronological data from two profiles across central Madagascar give apatite fission track and apatite (U–Th)/He ages ranging between 258 Ma and 176 Ma and from 239 Ma to 48 Ma, respectively. Thermal models derived from these data, as well as modelling of basement denudation and the sedimentary record, indicate that first order topography of central Madagascar developed mainly due to flexural uplift during Mesozoic times. This was in response to successive erosion and depositional loading associated with the sedimentation in the Morondava and Majunga basins, both of which are now exposed along the western margin of Madagascar. Our data suggest that the eastern margin of the island had a similar denudation history and was probably at a similar topographic level before the late Cretaceous break-up of Madagascar and the India/Seychelles block. Cretaceous normal faulting, without major amounts of denudation, led to the development of the present east coast topography defined by a tectonically juvenile escarpment. In the centre of the island Cenozoic tectonics and volcanism has had a minor and localised influence on the landscape of central Madagascar. 相似文献
8.
东非鲁伍马盆地深水区构造-沉积演化过程及油气地质特征 总被引:1,自引:0,他引:1
利用深水区的二维、三维地震资料开展构造-沉积演化研究,鲁伍马盆地二叠纪—早侏罗世为冈瓦纳陆内—陆间裂谷活动期,发育河流—湖泊沉积;中侏罗世—早白垩世为马达加斯加漂移期,位于剪切型大陆边缘,发育海陆过渡相沉积;晚白垩世—渐新世为被动大陆边缘期,深水沉积广泛发育,重力流沉积延伸至戴维隆起带;中新世—第四纪为东非裂谷海域分支活动期,陆坡和凯瑞巴斯地堑发育深水重力流沉积。盆地垂向上形成"断—坳—断"结构,二叠纪—早侏罗世及中新世—现今发育两期明显的裂谷活动。马达加斯加漂移期的海相泥岩为深水区的主力烃源岩,古近纪的陆坡深水浊积砂体为主要储层。东非裂谷海域分支的断层活动沟通了下伏烃源岩,晚期断层不发育的西部陆坡成为主要的油气聚集区。 相似文献
9.
The Sakoa Group is the lowermost stratigraphical succession of the Karoo Supergroup and the oldest sedimentary unit in Madagascar, spanning the Late Carboniferous through Early Permian epochs. The Sakoa Group is exposed in the southern Morondava Basin. It is predominantly a siliciclastic sequence comprising seven lithofacies associations: (1) diamictites; (2) conglomeratic sandstones; (3) sandstones; (4) interbedded thin sandstones and mudstones; (5) mudstones; (6) coals; and (7) limestones. These facies represent deposition in the early extensional stages of continental rift development. The sediments were deposited predominantly on alluvial fans, and in braided to meandering stream and overbank environments. Locally lacustrine and coal swamp environments formed in low areas of the basin floor during rift initiation. Subsidence rates remained fairly constant throughout the Early Permian and were accompanied by a gradual reduction in relief of the basin margins and an increased geomorphic maturity of the fluvial systems flowing across the basin floor. Near the end of the Early Permian the southern Morondava Basin was inundated by a marine transgression , which resulted in deposition of the Vohitolia Limestone. Subsequent tectonic uplift and erosion resulted in a regional unconformity between the Sakoa Group and the overlying Sakamena Group. 相似文献
10.
羌塘盆地是我国陆域上面积最大的海相盆地,前人对该盆地构造演化过程及其油气远景存在截然不同的观点。以最近完成的1︰ 5万地质调查为基础,本文再次讨论了南羌塘盆地构造演化过程及其油气远景。羌塘盆地中央近东西向的羌中隆起山脉将羌塘盆地分为南、北两部分。最近的研究表明,在寒武-奥陶纪之交,南、北羌塘块体被古大洋分隔开。北羌塘盆地南缘形成的晚三叠-早侏罗世的那底岗日组火山岩,其上部为流纹岩,表明晚三叠世南羌塘块体北向俯冲于北羌塘块体之下,在南羌塘块体北部形成了富含有机质的前陆盆地。南羌塘盆地南缘发育一套代表成熟海盆的侏罗纪复理石建造,表明南羌塘南部地区在早侏罗世具有被动大陆边缘的特点,随着南部班公-怒江洋的扩张,在南、北羌塘块体内分别沉积了侏罗纪-早白垩世的浅海相地层,以富含有机质礁灰岩为特征。盆地内部孕育了巨厚的晚白垩-古新世陆源碎屑岩,不整合覆盖于早期海相沉积岩之上,表明在该时期南羌塘块体逐渐从被动大陆边缘海相盆地转变为陆相盆地。新生代时期,印度与亚洲大陆持续汇聚,南羌塘盆地南向逆冲于拉萨块体之上,盆地内发育了多条大型逆冲断裂带,再次将盆地内部的上三叠统、侏罗系、白垩系富含有机质的海相礁灰岩深埋,这有利于油气资源的生成与保存。横跨南羌塘盆地的构造剖面显示盆地内部主要大型逆冲断裂带之间,构造变形较弱,发育宽缓的向斜构造,向斜核部发育新生代陆相地层,推测该新生代陆相地层之下保存有深埋的富含有机质的海相地层,因此,南羌塘盆地逆冲断裂带下盘和宽缓向斜核部区域可能具有良好的油气资源前景。 相似文献
11.
被动大陆边缘深海扇是当今海洋深水油气勘探的热点。识别深海扇,明确其时空演变特征,总结关键地质因素对其发育的控制作用,对于建立深海扇成因与预测地质模型具有重要意义。本文通过地震与钻井资料综合解释,分析塞内加尔盆地北部次盆白垩纪被动大陆边缘时期的构造-沉积演化特征,识别深海扇体,并分析其岩性、形态与规模的演变特征;然后分析海平面变化、陆源物质供给、陆坡与沟谷地貌等地质条件对深海扇体发育的控制作用。研究表明,研究区在白垩纪盆地被动大陆边缘阶段,经历了早白垩世的碳酸盐岩台地建设期、Albian-Santonian期碎屑岩沉积被陆坡内外分割的沉积期、Campanian-Maastrichtian期的碎屑岩缓坡沉积期等3个构造-沉积演化阶段;从早白垩世Aptian期到白垩纪末期发育了具有不同岩性、形态与规模特征的深海扇体。全球海平面变化、陆源碎屑供给、陆坡与沟谷地貌特征共同制约了深海扇的演化特征,但它们对深海扇发育与演化的影响作用又有所不同。全球海平面变化与陆源碎屑供给特征更多是影响了扇体的岩性粗细与规模,而陆坡沟谷地貌特征则直接决定了扇体的形态与分布。 相似文献
12.
AbstractThe Jurassic–Cretaceous Great Artesian Basin is the most extensive, and largest volume, sedimentary feature of continental Australia. The source of its mud-dominated Cretaceous infill is attributed largely to contemporary magmatism along the continental margin to the east, but the source of its Jurassic infill, dominated by quartz sandstone, remains unconstrained. This paper investigates the question of a Jurassic sediment source for the northern part of the basin. Jurassic uplift and exhumation of the continental margin crustal sector to the east provided the primary Jurassic sediment source. (U–Th)/He data are presented for zircon and apatite from Pennsylvanian to mid Permian granitoids of the Kennedy Igneous Association distributed within the northern Tasmanides between the Townsville and Cairns regions and for coeval granites of the Urannha batholith from the Mount Carlton district (N Bowen Basin), also within the northern Tasmanides. The data from zircon indicate widespread Jurassic exhumation of a crustal tract located to the east of the northern Great Artesian Basin and largely occupied by rocks of the Tasmanides. Detrital zircon age spectra for samples of the Jurassic Hutton and Blantyre sandstones from the northeastern margin of the Great Artesian Basin show their derivation to be largely from rocks of the northern Tasmanides. In combination, the detrital age spectra and (U–Th)/He data from zircon indicate exhumation owing to uplift generating appreciable physiographic relief along the north Queensland continental margin during the Jurassic, shedding sediment westward into the Great Artesian Basin during its early development. A portion of (U–Th)/He data for zircon are consistent with late Permian–mid Triassic exhumation within the Tasmanides, attributable to the influence of the Hunter--Bowen Orogeny. Evidence of Cretaceous and Paleocene exhumation episodes is also indicated for some samples, mainly by apatite (U–Th)/He analysis, consistent with data previously published from fission track studies. Overall, new data from the present study reveal that the exhumation related to Jurassic regional uplift and the subsequent erosional reworking of the northeast Australian continental margin is critical for the evolution and development of the northern side of the Great Artesian Basin in eastern Australia. Apart from this, another two previously suggested Permian–Triassic and Cretaceous exhumation and uplift episodes along the northeast Australian continental margin are also confirmed by the dataset of this study.
- KEY POINTS
U–Pb detrital zircon ages of sandstone samples from the northeastern Eromanga Basin reveal Paleozoic (480–280 Ma) and Proterozoic (1800–1400 Ma) age clusters.
(U–Th)/He zircon and apatite dating results of granitoids samples from Cairns, Townsville and the Mount Carlton districts are dominated by Jurassic (198–164 Ma) and Permian–Triassic (272–238 Ma) age clusters.
Combination of above two datasets proves the regional uplift-driving Jurassic exhumation episode in the northeast Australian continental is vital for the development of the northern Great Artesian Basin.
13.
C.A. Kogbe 《Cretaceous Research》1981,2(2):129-186
The Iullemmeden Basin (Mali-Niger-Benin-Nigeria) of tectono-epeirogenic origin was invaded several times by epicontinental transgressions during the Cretaceous and Paleocene.Three major subdivisions are recognized in the Nigerian section of the basin (the “Sokoto Basin”): (1) the lower, continental beds (= Continental Intercalaire) of Late Jurassic to Early Cretaceous age, (2) intermediate marine and brackish water deposits and (3) “Continental T Terminal” of upper Eocene-Miocene age.The geology of the Iullemmeden Basin is reviewed and updated. The relationships between the “Continental Intercalaire” of francophone authors and the Illo and Gundumi Formations are analysed and the type sections of the latter described. It is suggested that the Illo and Gundumi Formations are lateral equivalents.Detailed information on the formations of the Maastrichtian Rima Group is presented. It is concluded that there is no age difference of consequence between the Paleocene Dange, Kalambaina and Gamba Formations.The epicontinental transgressions are interpreted as coming from the north-east, east of the Hoggar massif during the Cenomanian and Turonian and west of the Hoggar during the Maastrichtian and Paleocene. The Sokoto Paleocene molluscan fauna is considered to be terminal Paleocene to Eocene and somewhat younger than the Ewekoro association of coastal Nigeria.A new interpretation of the Continental Terminal is presented. The structural history of the Sokoto Basin is reviewed and partly re-interpreted in the light of new field evidence. 相似文献
14.
中新生代天山隆升及其南北盆地分异与沉积环境演化 总被引:5,自引:2,他引:3
明确中生代以来天山隆升的时间顺序、隆升范围,及其与南北两侧盆地的沉积环境演化之间的关系,是天山两侧准噶尔盆地、吐哈盆地与塔里木等盆地原型恢复研究的重要需求。通过分析天山南北主要盆地类型、沉积充填、古气候变化,物源属性、边缘相带迁移反映的物源区远近变化与古水流特征,以及大量磷灰石裂变径迹测年数据认为,中新生代天山主要存在晚三叠世-早侏罗世、晚侏罗世-早白垩世、晚白垩世-始新世、中新世-第四纪的四期阶段隆升。在此基础上,编制了早侏罗世早期-第四纪的天山隆升范围及其南北盆地的沉积环境演化图,表明天山的四阶段隆升控制了北疆与南疆盆地由早、中侏罗世统一泛湖盆至晚侏罗-早白垩世盆地开始分异,再到新近纪以来彻底分割成独立盆地的沉积演化过程。同时,明确了天山南北两侧各盆地储层、烃源岩及盖层的重要形成期与天山隆升的关系,对有效拓展油气勘探范围有所启示。 相似文献
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《International Geology Review》2012,54(11):1417-1442
ABSTRACTThe Ordos Basin, situated in the western part of the North China Craton, preserves the 150-million-year history of North China Craton disruption. Those sedimentary sources from Late Triassic to early Middle Jurassic are controlled by the southern Qinling orogenic belt and northern Yinshan orogenic belt. The Middle and Late Jurassic deposits are received from south, north, east, and west of the Ordos Basin. The Cretaceous deposits are composed of aeolian deposits, probably derived from the plateau to the east. The Ordos Basin records four stages of volcanism in the Mesozoic–Late Triassic (230–220 Ma), Early Jurassic (176 Ma), Middle Jurassic (161 Ma), and Early Cretaceous (132 Ma). Late Triassic and Early Jurassic tuff develop in the southern part of the Ordos Basin, Middle Jurassic in the northeastern part, while Early Cretaceous volcanic rocks have a banding distribution along the eastern part. Mesozoic tectonic evolution can be divided into five stages according to sedimentary and volcanic records: Late Triassic extension in a N–S direction (230–220 Ma), Late Triassic compression in a N–S direction (220–210 Ma), Late Triassic–Early Jurassic–Middle Jurassic extension in a N–S direction (210–168 Ma), Late Jurassic–Early Cretaceous compression in both N–S and E–W directions (168–136 Ma), and Early Cretaceous extension in a NE–SW direction (136–132 Ma). 相似文献
17.
尚义盆地形成于早侏罗世-早白垩世,盆地内沉积了一套以紫红色、灰绿色陆源碎屑岩为主的地层,仅在晚侏罗世-早白垩世地层局部夹薄层玄武安山质火山岩。通过系统分析尚义盆地的沉积岩、沉积相带展布特征及古水流、砾石成分等,分析了早侏罗世-早白垩世盆地的物源区、汇水中心及古气候的演化,恢复了早侏罗世-早白垩世盆地古地理格局。同时,在前人研究基础上,结合尚义盆地的沉积-充填样式,重点总结和综合分析了盆地内熔积岩、辉绿岩、边界断层等的发育特征,初步推断晚侏罗世-早白垩世尚义盆地为伸展断陷盆地。 相似文献
18.
扬子北缘黄陵地区古构造应力场于晚中生代经历发生了重大转变,是扬子板块与华北板块在三叠纪碰撞造山之后陆内构造变形的体现。由黄陵背斜周缘晚中生代盆地充填记录所反映出这一变革的起始时间为中侏罗世晚期。早侏罗世-中侏罗世早期,盆地内沉积了以桐竹园组为代表的河流-湖泊相岩层,由沉积碎屑成分和古水流统计所得出的物源区为北部的秦岭地区,黄陵背斜上部可能也接受了碎屑沉积;中侏罗世晚期-晚侏罗世,沉积中心发生了改变,表现为仅仅在黄陵背斜西侧的秭归盆地内有所保存,沉积环境以曲流河到辫状河流和三角洲为主,物源区则局限于黄陵背斜;早白垩世初期,周坪盆地和宜昌盆地为沉积中心,近缘冲积扇和辫状河流体系占据主体,物源区依然为黄陵地区,两盆地在黄陵背斜南缘可能相连,黄陵背斜上部的原下侏罗统被剥蚀;早白垩世晚期-晚白垩世,远安盆地逐渐发育,盆地西缘为冲积扇-辫状河流体系,中、 东部则以曲流河-湖泊沉积环境为主体,并间有干旱沙漠环境。原型盆地再造结果显示,早侏罗世-中侏罗世早期盆地展布具有近东西向特点,古地貌总体呈现出北部为山脉、 南部为盆地的格局;中侏罗世晚期以来,盆地呈近南北向,黄陵背斜逐渐形成山脉,盆地位于其东西两侧。两期盆地沉积特征反映了扬子北缘古构造应力场由近南北向转变为近东西向的过程。 相似文献
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准噶尔盆地南缘西段侏罗系—白垩系储层油气勘探潜力巨大,但目前有关其物源条件及沉积背景认识极为有限,严重制约了后续储层的有效预测和勘探。据此,通过对侏罗系—白垩系储层碎屑矿物及砾石成分特征、重矿物类型及组合特征、古水流特征、地层岩性比例特征等进行深入对比分析,并在此基础上结合区域构造演化对各地层沉积物源体系及其演化进行详细探讨。研究结果表明:侏罗系—白垩系储层物源主体受控于北部和南部再循环沉积岩系山体,但仍受北部扎伊尔山和南部中天山结晶变质岩系山体源区的影响,其影响程度自早侏罗世到早白垩世逐渐降低。下组合沉积期南部、北部物源同时存在,且研究区存在混源特征,但不存在统一且稳定的沉积中心。早侏罗世沉积物源背景相对稳定,原始沉积边界距现今最远;自中侏罗世开始受控于车莫古隆起演化影响,北部物源得以加强,同时地层发育不均衡并存在剥蚀现象;自晚侏罗世开始直至早白垩世,周缘沉积岩系山体隆升范围和幅度不断加大,并阻隔结晶变质岩系山体供源路径,沉积边界也随之逐渐萎缩,但这一时期北部物源可为优势物源,且研究区整体处于“填平补齐”状态,即齐古组沉积期可存在沟谷—残丘地貌特征,而下白垩统清水河组沉积前研究区整体呈准平原化状态。 相似文献
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侏罗系是柴达木盆地最重要的源储层系之一。通过野外地质、剖面实测、地震解释、显微构造分析等大量系列资料的综合应用与分析,认为研究区自中生代以来,经历了印支期右行逆冲-走滑构造运动、早—中侏罗世伸展运动、早白垩世北西-南东向挤压及新生代南北向挤压运动,它们与早侏罗世至中侏罗世早期(小煤沟组至大煤沟组)在NE向伸展应力场作用下形成的断陷盆地、中侏罗世晚期至晚侏罗世(彩石岭组—洪水沟组)热力沉降坳陷盆地、早白垩世南北向挤压坳陷盆地密切相关。侏罗纪原型盆地发育三类沉积边界,即盆缘不整合边界(缓坡型和陡坡型边界)、盆内正断层边界、后期逆断层改造边界。不同的现存盆地边界类型对原型盆地恢复的作用不同。侏罗纪盆地以东昆仑构造带为界具有"北陆南洋"的古地理格局,柴达木地区的侏罗纪盆地主要发育在沿岸造山带和岛弧带的山前坳陷以及薄弱的柴北缘加里东俯冲碰撞带之上,形成相对分隔的独立盆地群。柴达木早、中、晚侏罗世原型盆地的分布因受到古特提斯洋向北偏东方向的俯冲作用和阿尔金断裂左旋走滑作用的影响,其沉积中心和沉积范围呈现出从早到晚向东北方向逐渐迁移的规律。早侏罗世盆地的沉积沉降中心主要位于柴北缘西部的冷湖—马海一带,中侏罗世盆地的沉积沉降中心主要位于柴北缘中段的大柴旦—怀头他拉一带,而晚侏罗世盆地的沉积沉降中心主要位于德令哈—乌兰一带。 相似文献