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1.
侏罗纪时东南亚大陆上形成两个大盆地,西为海相盆地,东为陆相红盆。白垩纪时大盆地闭合或解体。第三纪出现裂谷盆地,其发育受燕山期构造格局控制;拉张应力自南向北变弱,裂谷发育自南向北变晚。第四纪为上叠盆地阶段。滇西与泰国各时期盆地的对比研究有助于更好地认识其演化特征,恢复东南亚大陆侏罗纪以来不断碎裂、局部解体的历史。 相似文献
2.
扬子地块东北缘中元古代的大地构造 总被引:3,自引:0,他引:3
扬子地块东北缘存在四条主要的中元古代变质带,自南向北依次为江南变质带,沿江变质带,云台-张八岭变质带和连云港-泗阳变质带。它们分别为中元古代的古弧后盆地,火山岛弧,裂谷及弧前盆地。扬子地块东北缘中元古代为活动大陆边缘构造体系,苏胶变质造山带应解体,其中一部分属扬子大陆边缘体系。 相似文献
3.
班公湖—怒江构造带西段三叠纪—侏罗纪构造—沉积演化 总被引:20,自引:2,他引:20
班公湖-怒江构造带西段在大地构造位置上处于特提斯构造域东端,横跨班公湖-怒江断裂带。三叠纪-株罗纪期间,其构造-沉积演化经历了大陆初始裂谷(T)、原洋裂谷(J1)、残余弧后盆地(J2-J3)阶段。初始裂谷阶段的拉张是呈南断北超的半地堑式由东向西进行的,逐渐形成地堑式原洋裂谷盆地。中晚侏罗世,南部新特提斯洋壳开始北各俯冲,产生的区域挤压应力使原洋裂谷逐渐封闭,裂谷盆地的小洋壳表现出以南向俯冲为主的双向式腑冲,同时伴生区域热沉降,盆地具残余弧后盆地的性质。该阶段,羌南地区发育碳酸盐岩为主的稳定陆缘沉积,冈度斯-念青唐古拉板片北部则形成广泛南超的近源碎屑沉积。 相似文献
4.
非洲地区盆地演化与油气分布 总被引:2,自引:0,他引:2
非洲地区盆地整体勘探程度较低,待发现资源量大,是当前油气勘探开发的热点地区之一。非洲板块在显生宙主要经历了冈瓦纳大陆形成、整体运动和裂解3个构造演化阶段,形成多种不同类型的盆地。通过板块构造演化和原型盆地研究及石油地质综合分析,明确了不同类型盆地的构造特征与油气富集规律。北非克拉通边缘盆地形成于古生代早期,受海西运动影响,油气主要富集在挤压背景下形成的大型穹隆构造之中,以古生界含油气系统为主;北非边缘裂谷盆地海西运动之后普遍经历了裂谷和沉降,裂谷期各盆地沉降幅度和沉降中心的差异导致了油气成藏模式和资源潜力的差异;东、西非被动陆缘盆地形成于中生代潘吉亚大陆的解体、大西洋和印度洋张裂的过程中,西非被动陆缘盆地普遍发育含盐地层,形成盐上和盐下两套含油气系统,东非被动陆缘盆地结构差异较大,油气分布主要受盆地结构控制;中西非裂谷系是经历早白垩世、晚白垩世和古近纪3期裂谷作用而形成的陆内裂谷盆地,受晚白垩世非洲板块与欧亚板块碰撞的影响,近东西向展布盆地抬升剧烈,油气主要富集在下白垩统,北西南东向盆地受影响较弱,油气主要富集在上白垩统和古近系之中;新生代东非裂谷系盆地和红海盆地形成时间相对较晚,以新生界含油气系统为主,新生代三角洲盆地中油气分布主要受三角洲砂(扇)体展布和盆地结构所控制。 相似文献
5.
李文汉 《沉积与特提斯地质》1988,8(2):60-66
一、沉积在侏罗纪特提斯洋裂谷盆地(瑞士东阿尔卑斯)中的碳酸盐浊积岩序列沿未来的侏罗纪特提斯洋南部大陆边缘形成的盆地中的同裂谷沉积物,在瑞士东阿尔卑斯由厚达500m的碳酸盐浊积岩序列与生物浊积泥灰岩和石灰岩互层构成。在边界断层槽内没有海底扇;相反,作为线物源区的断层崖、不对称的几何形状以及盆地的演化决定了再沉积碳酸盐岩的分布。最丰富的再沉积物是生物的和岩屑的粒状灰岩和泥粒灰岩,其沉积构造具有广泛的从颗 相似文献
6.
大陆裂谷盆地钾盐矿床特征与成矿作用 总被引:13,自引:0,他引:13
全球板块运动对表生成钾控制明显, 即从古生代到中新生代, 从巨型稳定克拉通陆表海盆成钾, 到中生代特提斯海域海盆成钾, 再到新生代的大陆裂谷盆地成钾, 地球表生成钾模式发生了重大转变; 成钾物质来源从海水补给为主, 转变为非海相(以火山活动带来深部物质和陆表水)与海相混合型, 甚至以非海相深部物质补给为主。全球裂谷成钾时期正好处于Pangea超大陆解体及新特提斯洋闭合时期, 成钾的裂谷型蒸发岩盆地也主要位于这两个构造域内, 这些进一步表明裂谷成钾是地球板块构造运动演化历史的必然结果。典型的裂谷盆地钾盐矿床有: 大西洋裂谷形成初期沉积的刚果(布)白垩纪钾盐矿、欧洲大陆莱茵地堑第三纪钾盐矿、非洲大陆埃塞俄比亚达纳基尔钾盐矿等; 同时, 还有众多裂谷盆地蕴藏有富钾卤水矿, 如死海裂谷富钾卤水、东非大裂谷一些富钾盐湖、美国加州索尔顿海高温富钾热卤以及中国江陵凹陷富钾热卤等。这些钾盐矿的共同特点是: 盆地内发育火山岩和温热泉, 具有深源补给的明显特征; 尽管裂谷盆地规模一般很小, 但形成的钾盐规模最大可达数十亿吨。总结世界大陆裂谷盆地钾盐矿床特征、物质来源与成矿作用, 提出了大陆裂谷型小盆地成钾模式。其裂谷成钾过程可分解为“二个阶段”, 第一阶段, 地表盐湖-太阳能作用, 第二阶段, 埋藏-岩浆热能作用; 成钾作用有三个, 即蒸发沉积作用、沉积后淋滤改造作用和埋藏变质改造作用。中国中新生代裂谷型盆地比较发育, 进一步研究大陆裂谷盆地成钾作用, 可以为此类盆地找钾提供理论依据和指导。 相似文献
7.
侏罗纪是中亚和中国西部地区沉积盆地主要形成时期,这表现在两个方面:(1)先期存在的盆地在此阶段沉积范围持续扩大;(2)形成了许多新的侏罗纪沉积盆地.本文通过对劳亚大陆南部侏罗纪特提斯北带构造特征、诸盆地早-中侏罗世岩相古地理和构造样式的分析,表明中国西部与中亚地区在侏罗纪时虽然都处于新特提斯北部被动大陆边缘,但由于受帕米尔弧向北推挤的影响,以及昆仑构造带与塔拉斯-费尔干纳断裂和阿尔金大型走滑断裂的存在,这两个地区的侏罗纪盆地具有完全不同的构造起因.以塔拉斯-费尔干纳断裂为界,西南侧中亚地区的侏罗纪沉积盆地主要是由新特提斯北部大陆边缘的被动伸展形成;东北侧中国西部的侏罗纪沉积盆地则主要发育于区域性挤压构造背景之下,形成的主要机制是重力陷落.此外,沿塔拉斯-费尔干纳断裂还存在几个侏罗纪的走滑拉分盆地.中国西部与中亚地区侏罗纪盆地的不同成因特征对盆地的比较研究和寻找侏罗系烃源岩都具有重要意义. 相似文献
8.
华南新元古代裂谷盆地演化 总被引:6,自引:0,他引:6
《矿物岩石》2001,21(3):135-145
沉积学研究表明,华南新元古代沉积盆地具典型裂谷盆地沉积演化特征.代表裂谷盆地早期形成阶段的成因相组合有冲洪积相组合、陆相(或海相)火山岩及火山碎屑岩相组合、滨浅海相沉积组合、淹没碳酸盐台地及欠补偿盆地黑色页岩相组合;而代表中、后期形成阶段的成因相组合有滨岸边缘相至深海相组合,冰期冰积岩相组合、碳酸盐岩及碳硅质细碎屑岩相组合.华南裂谷盆地岩相古地理演化经历了5个重要的时期,整体上反映了一个由陆变海、由地堑-地垒相间盆地变广海盆地、由浅海变深海、盆地由小变大的演化过程.裂谷盆地的形成经历了裂谷基的形成、地幔柱作用与裂谷体的形成、被动沉降(下拗)与裂谷盖的形成三个阶段.华南裂谷盆地的形成演化与Rodinia超大陆在新元古代时期的裂解作用密切相关,它是超大陆解体过程的一个重要组成部分. 相似文献
9.
大别山周缘盆地物源研究:新结果及运用 总被引:3,自引:0,他引:3
叙述单颗粒碎屑矿物在大别山周缘盆地物源分析中的运用。现代河流沉积与大别山源区的对比研究表明碎屑石榴石、K 白云母和电气石的化学组成可以有效地被用于物源分析。它们在侏罗纪—白垩纪—古近纪沉积中的特征揭示了大别山源区岩石组成的复杂性,由扬子大陆深俯冲折返所形成的高压—超高压变质岩在白垩纪—古近纪逐渐向东南缘盆地提供了重要的物源, 在侏罗纪时期主要分布在大别山北缘盆地的源区。石炭纪时期大别山北缘盆地中碎屑Cr 尖晶石的化学组成和碎屑锆石U Pb年龄结构指示源区岩石组成主要为早古生代华北大陆南缘活动大陆边缘的特征;此外,锆石U Pb年龄指示源区岩石也具有扬子大陆的特征。 相似文献
10.
华南新元古代裂谷盆地演化——Rodinia超大陆解体的前奏 总被引:26,自引:0,他引:26
沉积学研究表明,华南新元古代沉积盆地具典型裂谷盆地沉积演化特征。代表裂谷盆地早期形成阶段的成因相组合有:冲洪积相组合、陆相(或海相)火山岩及火山碎屑岩相组合、滨浅海相沉积组合、淹没碳酸盐台地及欠补偿盆地黑色页岩相组合;而代表中、后期形成阶段的成因相组合有:滨岸边缘相至深海相组合,冰期冰积岩相组合、碳酸盐岩及碳硅质细碎岩相组合。华南裂谷盆地岩相古地理演化经历了5个重要的时期,整体上反映了一个由陆变海、由地堑-地垒相间盆地变广海盆地、由浅海变深海、盆地上小变大的演化过程。裂谷盆地的形成经历了裂谷基的形成、地幔柱作用与裂谷体的形成,被动沉降(下坳)与裂谷盖的形成三个阶段。华南裂谷盆地的形成演化与Rodinia超大陆在新元古代时期的裂解作用密切相关,它是超大陆解体过程的一个重要组成部分。 相似文献
11.
关于湘东南晚三叠世-侏罗纪沉积盆地性质存在挤压相关类前陆盆地及断陷盆地等不同认识。沉积物分布及岩相特征研究表明:湘东南晚三叠世-早侏罗世早期为海相-海陆交互相沉积环境, 早侏罗世晚期-中侏罗世早期为陆相沉积环境; 晚三叠世盆地为分布于茶陵-郴州大断裂东侧(上盘)的北北东-近南北向狭长海湾, 早侏罗世开始盆地向东、西两侧扩展; 晚三叠世-侏罗纪沉积横向上覆于相对较老的地层之上, 表明湘东南晚三叠世-侏罗纪盆地不是南北向挤压形成的类前陆拗陷盆地。结合区域构造背景, 提出盆地的形成主要与区域南北向挤压下先期北北东向断裂产生东西方向伸展有关, 一定程度上印证了印支运动构造线为北北东向。海相至陆相的演化过程暗示研究区以南在早侏罗世晚期开始因区域南北向挤压形成了东西向隆起, 说明盆地发育后期伸展活动的同时却处于区域挤压拗陷构造背景之中, 反映出晚三叠世-侏罗纪盆地演化期间华南地区伸展/挤压构造体制具复杂的时空变化。 相似文献
12.
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
13.
14.
《Geodinamica Acta》2001,14(1-3):45-55
Field studies on the Neogene successions in south of İzmir reveal that subsequent Neogene continental basins were developed in the region. Initially a vast lake basin was formed during the Early–Middle Miocene period. The lacustrine sediments underwent an approximately N–S shortening deformation to the end of Middle Miocene. A small portion of the basin fill was later trapped within the N–S-trending, fault-bounded graben basin, the Çubukludağ graben, opened during the Late Miocene. Oblique-slip normal faults with minor sinistral displacement are formed possibly under N–S extensional regime, and controlled the sediment deposition. Following this the region suffered a phase of denudation which produced a regionwide erosional surface suggesting that the extension interrupted to the end of Late Miocene–Early Pliocene period. After this event the E–W-trending major grabens and horsts of western Anatolia began to form. The graben bounding faults cut across the Upper Miocene–Pliocene lacustrine sediments and fragmented the erosional surface. The Çubukludağ graben began to work as a cross graben between the E–W grabens, since that period. 相似文献
15.
Ömer Feyzi Gürer Ercan Sanğu Muzaffer Özburan Alper Gürbüz Nuran Sarica-Filoreau 《International Journal of Earth Sciences》2013,102(8):2199-2221
Southwestern Turkey experienced a transition from crustal shortening to extension during Late Cenozoic, and evidence of this was recorded in four distinct basin types in the Mu?la–Gökova Gulf region. During the Oligocene–Early Miocene, the upper slices of the southerly moving Lycian Nappes turned into north-dipping normal faults due to the acceleration of gravity. The Kale–Tavas Basin developed as a piggyback basin along the fault plane on hanging wall blocks of these normal faults. During Middle Miocene, a shift had occurred from local extension to N–S compression/transpression, during which sediments in the Eskihisar–T?naz Basins were deposited in pull-apart regions of the Menderes Massif cover units, where nappe slices were already eroded. During the Late Miocene–Pliocene, a hiatus occurred from previous compressional/transpressional tectonism along intermountain basins and Yata?an Basin fills were deposited on Menderes Massif, Lycian Nappes, and on top of Oligo–Miocene sediments. Plio-Quaternary marked the activation of N–S extension and the development of the E–W-trending Mu?la–Gökova Grabens, co-genetic equivalents of which are common throughout western Anatolia. Thus, the tectonic evolution of the western Anotolia during late Cenozoic was shifting from compressional to extensional with a relaxation period, suggesting a non-uniform evolution. 相似文献
16.
Fetheddine Melki Taher Zouaghi Mohamed Ben Chelbi Mourad Bédir Fouad Zargouni 《Comptes Rendus Geoscience》2010,342(9):741-753
The structural pattern, tectono-sedimentary framework and geodynamic evolution for Mesozoic and Cenozoic deep structures of the Gulf of Tunis (north-eastern Tunisia) are proposed using petroleum well data and a 2-D seismic interpretation. The structural system of the study area is marked by two sets of faults that control the Mesozoic subsidence and inversions during the Paleogene and Neogene times: (i) a NE-SW striking set associated with folds and faults, which have a reverse component; and (ii) a NW–SE striking set active during the Tertiary extension episodes and delineating grabens and subsiding synclines. In order to better characterize the tectono-sedimentary evolution of the Gulf of Tunis structures, seismic data interpretations are compared to stratigraphic and structural data from wells and neighbouring outcrops. The Atlas and external Tell belonged to the southernmost Tethyan margin record a geodynamic evolution including: (i) rifting periods of subsidence and Tethyan oceanic accretions from Triassic until Early Cretaceous: we recognized high subsiding zones (Raja and Carthage domains), less subsiding zones (Gamart domain) and a completely emerged area (Raouad domain); (ii) compressive events during the Cenozoic with relaxation periods of the Oligocene-Aquitanian and Messinian-Early Pliocene. The NW–SE Late Eocene and Tortonian compressive events caused local inversions with sealed and eroded folded structures. During Middle to Late Miocene and Early Pliocene, we have identified depocentre structures corresponding to half-grabens and synclines in the Carthage and Karkouane domains. The north–south contractional events at the end of Early Pliocene and Late Pliocene periods are associated with significant inversion of subsidence and synsedimentary folded structures. Structuring and major tectonic events, recognized in the Gulf of Tunis, are linked to the common geodynamic evolution of the north African and western Mediterranean basins. 相似文献
17.
Apatite fission‐track analyses on samples from eastern Sardinia document a complex tectonic history, whose reconstruction is problematic because of the reactivation of faults and structures at different times from Jurassic to Miocene. The oldest ages (150–154 Ma) have been detected on the southern margin of the Gulf of Orosei and are related to the extensional tectonics that characterize the European passive margin during Early and Middle Jurassic times. Thermal modelling of these data allows reconstruction of the burial history of the Mesozoic basin and estimation of a sedimentary thickness of 2000 m. Part of these sediments was eroded during the following uplift, documented by mid‐Cretaceous fission‐track ages. A further exhumation episode of Eocene age has been revealed by fission‐track data on granite samples, and has been inferred to be related to the Alpine orogenic phase. This tectonic episode caused the exhumation of crustal blocks bound by faults that were finally reactivated during the Late Oligocene–Early Miocene. 相似文献
18.
《Geodinamica Acta》2001,14(1-3):147-158
Central Anatolia has undergone complex Neotectonic deformation since Late Miocene–Pliocene times. Many faults and intracontinental basins in this region were either formed, or have been reactivated, during this period. The eastern part of central Anatolia is dominated by a NE–SW-trending, left lateral transcurrent structure named the Central Anatolian fault zone located between Sivas in the northeast and west of Mersin in the southwest. Around the central part, it is characterized by transtensional depressions formed by left stepping and southward bending of the fault zone.Pre-Upper Miocene basement rocks of the region consist of the central Anatolian crystalline complex and a sedimentary cover of Tertiary age. These rock units were strongly deformed by N–S convergence. The entire area emerged to become the site of erosion and formed a vast plateau before the Late Miocene. A NE–SW-trending extensional basin developed on this plateau in Late Miocene–Early Pliocene times. Rock units of this basin are characterized by a thick succession of pyroclastic rocks intercalated with calcalkaline–alkaline volcanics. The volcanic sequence is unconformably overlain by Pliocene lacustrine–fluviatile deposits intercalated with ignimbrites and tuffs. Thick, coarse grained alluvial/colluvial fan deposits of marginal facies and fine grained clastics and carbonates of central facies display characteristic synsedimentary structures with volcanic intercalations. These are the main lines of evidence for development of a new transtensional Hırka–Kızılırmak basin in Pliocene times. Reactivation of the main segment of the Central Anatolian fault zone has triggered development of depressions around the left stepping and southward bending of the central part of this sinistral fault zone in the ignimbritic plateau during Late Pliocene–Quaternary time. These transtensional basins are named the Tuzla Gölü and Sultansazlığı pull-apart basins. The Sultansazlığı basin has a lazy S to rhomboidal shape and displays characteristic morphologic features including a steep and stepped western margin, large alluvial and colluvial fans, and a huge composite volcano (the Erciyes Dağı).The geometry of faulting and formation of pull-apart basins can be explained within the framework of tectonic escape of the wedge-like Anatolian block, bounded by sinistral East Anatolian fault zone and dextral North Anatolian transform fault zone. This escape may have been accomplished as lateral continental extrusion of the Anatolian Plate caused by final collision of the Arabian Plate with the Eurasian Plate. 相似文献
19.
《Journal of Asian Earth Sciences》1999,17(1-2):157-181
The Kutai Basin occupies an area of extensive accommodation generated by Tertiary extension of an economic basement of mixed continental/oceanic affinity. The underlying crust to the basin is proposed here to be Jurassic and Cretaceous in age and is composed of ophiolitic units overlain by a younger Cretaceous turbidite fan, sourced from Indochina. A near complete Tertiary sedimentary section from Eocene to Recent is present within the Kutai Basin; much of it is exposed at the surface as a result of the Miocene and younger tectonic processes. Integration of geological and geophysical surface and subsurface data-sets has resulted in re-interpretation of the original facies distributions, relationships and arrangement of Tertiary sediments in the Kutai Basin. Although much lithostratigraphic terminology exists for the area, existing formation names can be reconciled with a simple model explaining the progressive tectonic evolution of the basin and illustrating the resulting depositional environments and their arrangements within the basin. The basin was initiated in the Middle Eocene in conjunction with rifting and likely sea floor spreading in the Makassar Straits. This produced a series of discrete fault-bounded depocentres in some parts of the basin, followed by sag phase sedimentation in response to thermal relaxation. Discrete Eocene depocentres have highly variable sedimentary fills depending upon position with respect to sediment source and palaeo water depths and geometries of the half-graben. This contrasts strongly with the more regionally uniform sedimentary styles that followed in the latter part of the Eocene and the Oligocene. Tectonic uplift documented along the southern and northern basin margins and related subsidence of the Lower Kutai Basin occurred during the Late Oligocene. This subsidence is associated with significant volumes of high-level andesitic–dacitic intrusive and associated volcanic rocks. Volcanism and uplift of the basin margins resulted in the supply of considerable volumes of material eastwards. During the Miocene, basin fill continued, with an overall regressive style of sedimentation, interrupted by periods of tectonic inversion throughout the Miocene to Pliocene. 相似文献