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1.
Genesis of the so‐called Bentong‐Raub Suture of Malay Peninsula does not fit to the model of subduction‐related collision. It has evolved from transpression tectonics resulting closure and exhumation of the inland basin which underwent extensive back‐arc extension during Triassic. Crust having similar thickness (average ~35 km) below entire Malay Peninsula nagate collision of two separate continental blocks rather supports single continental block that collided with South China continental block during Permo‐Triassic. Westward subduction of intervening sea (Proto South China Sea) below Malay Peninsula resulted in widespread I‐ and S‐Type granitization and volcanism in the back‐arc basins during Triassic. Extensive occurrence of Permo‐Triassic Pahang volcanics of predominantly rhyolitic tuff suggest its derivation from back‐arc extension. Back‐arc extension, basin development and sedimentation of the central belt of the peninsula continued until Cretaceous. A‐Type granite of metaluminous to peraluminous character indicates their emplacement in an intraplate tectonic setting. Malay Peninsula suffered an anticlockwise rotation due to the rifting of Luconia–Dangerous Grounds from the east Asia in the Late Cretaceous–Early Tertiary. Extensive ductile and brittle deformation including crustal segmentation, pull‐apart fracturing and faulting occurred during the closure and exhumation of the basins developed in the peninsula during Late Cretaceous–Early Tertiary. Crustal shortening in the central belt of the peninsula has been accomodated through strike‐slip displacement, shearing and uplift. 相似文献
2.
Cretaceous deformation history of the middle Tan-Lu fault zone in Shandong Province, eastern China 总被引:13,自引:0,他引:13
Based on field analysis of fault-slip data from different rock units of the Cretaceous basins along the middle part of the Tan-Lu fault zone (Shandong Province, eastern China), we document polyphase tectonic stress fields and address the changes in sense of motion of the Tan-Lu fault zone during the Cretaceous. The Cretaceous deformation history of the Tan-Lu fault zone can be divided into four main stages. The first stage, during the earliest Cretaceous, was dominated by N-S extension responsible for the formation of the Jiaolai basin. We interpret this extension to be related to dextral strike-slip pull-apart opening guided by the Tan-Lu fault zone. The second stage, during the middle Early Cretaceous, was overwhelmingly rift-dominated and characterized by widespread silicic to intermediate volcanism, normal faulting and basin subsidence. It was at this stage that the Tan-Lu-parallel Yi-Shu Rift was initiated by E-W to WNW-ESE extension. The tectonic regime then changed during the late Early Cretaceous to NW-SE-oriented transpression, causing inversion of the Early Cretaceous rift basin and sinistral slip along the Tan-Lu fault zone. During the Late Cretaceous, dextral activation of the Tan-Lu fault zone resulted in pull-apart opening of the Zhucheng basin, which was subsequently deformed by NE-SW compression. This deformation chronology of the Tan-Lu fault zone and the associated Cretaceous basins allow us to constrain the regional kinematic models as related to subduction along the eastern margin of Asia, or related to collision in the Tibet region. 相似文献
3.
自中三叠世扬子与华北板块发生碰撞—深俯冲作用以来,大别造山带南界上的襄樊—广济断裂带主要经历过两次变形事件: 1)早期变形事件发生在中三叠世末—晚三叠世初的造山带折返阶段,表现为造山带南边界上的韧性剪切带。这期北西—南东走向的剪切带向南西陡倾,发育北西—南东向的矿物拉伸线理,主要为右行走滑的运动性质,属于造山带斜向折返的侧边界走滑剪切带。造山带折返过程中将前陆褶断带北缘原先东西向褶皱改造为北西—南东走向。2)晚期变形事件发生在晚侏罗世,表现为脆性逆冲断层,使得前陆褶断带向北东逆冲在造山带南缘之上,同时在前陆上形成了一系列的逆冲断层。该断裂带的晚期逆冲活动与郯庐断裂带左行平移同时发生,代表了滨太平洋构造活动的开始。 相似文献
4.
南沙地块构造格局及其演化特征 总被引:17,自引:5,他引:12
将南沙地块及其周边地块置于统一的地球动力学背景下,根据地球物理、地层展布、构造变形等特征,确立了南沙地块的一级构造边界,提出南沙地块的演化与古南海及现今南海的演化密不可分。古南海分隔了南沙地块和加里曼丹—巴拉望地块,随着古南海由西南往东北的剪刀状南向俯冲封闭和现今南海的张开,南沙地块和加里曼丹—巴拉望地块之间先后在始新世—晚中新世发生B型俯冲、A型俯冲及碰撞作用,形成沙捞越俯冲碰撞带,并在该带北侧形成南沙地块前陆盆地区、南沙地块隆起区及南海深海盆3个构造单元。 相似文献
5.
DMITRIENKO Liudmila V. WANG Pengcheng LI Sanzhong CAO Xianzhi Ian SOMERVILLE ZHOU Zaizheng HU Mengying SUO Yanhui GUO Lingli WANG Yongming LI Xiyao LIU Xin YU Shengyao ZHU Junjiang 《《地质学报》英文版》2018,92(2):814-849
The East Asian geological setting has a long duration related to the superconvergence of the Paleo‐Asian, Tethyan and Paleo‐Pacific tectonic domains. The Triassic Indosinian Movement contributed to an unified passive continental margin in East Asia. The later ophiolites and I‐type granites associated with subduction of the Paleo‐Pacific Plate in the Late Triassic, suggest a transition from passive to active continental margins. With the presence of the ongoing westward migration of the Paleo‐Pacific Subduction Zone, the sinistral transpressional stress field could play an important role in the intraplate deformation in East Asia during the Late Triassic to Middle Jurassic, being characterized by the transition from the E‐W‐trending structural system controlled by the Tethys and Paleo‐Asian oceans to the NE‐trending structural system caused by the Paleo‐Pacific Ocean subduction. The continuously westward migration of the subduction zones resulted in the transpressional stress field in East Asia marked by the emergence of the Eastern North China Plateau and the formation of the Andean‐type active continental margin from late Late Jurassic to Early Cretaceous (160‐135 Ma), accompanied by the development of a small amount of adakites. In the Late Cretaceous (135‐90 Ma), due to the eastward retreat of the Paleo‐Pacific Subduction Zone, the regional stress field was replaced from sinistral transpression to transtension. Since a large amount of late‐stage adakites and metamorphic core complexes developed, the Andean‐type active continental margin was destroyed and the Eastern North China Plateau started to collapse. In the Late Cretaceous, the extension in East Asia gradually decreased the eastward retreat of the Paleo‐Pacific subduction zones. Futhermore, a significant topographic inversion had taken place during the Cenozoic that resulted from a rapid uplift of the Tibet Plateau resulting from the India‐Eurasian collision and the formation of the Bohai Bay Basin and other basins in the East Asian continental margin. The inversion caused a remarkable eastward migration of deformation, basin formation and magmatism. Meanwhile, the basins that mainly developed in the Paleogene resulted in a three‐step topography which typically appears to drop eastward in altitude. In the Neogene, the basins underwent a rapid subsidence in some depressions after basin‐controlled faulting, as well as the intracontinental extensional events in East Asia, and are likely to be a contribution to the uplift of the Tibetan Plateau. 相似文献
6.
The Armutlu Peninsula and adjacent areas in NW Turkey play a critical role in tectonic reconstructions of the southern margin of Eurasia in NW Turkey. This region includes an inferred Intra-Pontide oceanic basin that rifted from Eurasia in Early Mesozoic time and closed by Late Cretaceous time. The Armutlu Peninsula is divisible into two metamorphic units. The first, the Armutlu Metamorphics, comprises a ?Precambrian high-grade metamorphic basement, unconformably overlain by a ?Palaeozoic low-grade, mixed siliciclastic/carbonate/volcanogenic succession, including bimodal volcanics of inferred extensional origin, with a possibly inherited subduction signature. The second unit, the low-grade
znik Metamorphics, is interpreted as a Triassic rift infilled with terrigenous, calcareous and volcanogenic lithologies, including basalts of within-plate type. The Triassic rift was unconformably overlain by a subsiding Jurassic–Late Cretaceous (Cenomanian) passive margin including siliciclastic/carbonate turbidites, radiolarian cherts and manganese deposits. The margin later collapsed to form a flexural foredeep associated with the emplacement of ophiolitic rocks in Turonian time. Geochemical evidence from meta-basalt blocks within ophiolite-derived melange suggests a supra-subduction zone origin for the ophiolite. The above major tectonic units of the Armutlu Peninsula were sealed by a Maastrichtian unconformity. Comparative evidence comes from the separate Almacık Flake further east.Considering alternatives, it is concluded that a Mesozoic Intra-Pontide oceanic basin separated Eurasia from a Sakarya microcontinent, with a wider Northern Neotethys to the south. Lateral displacement of exotic terranes along the south-Eurasian continental margin probably also played a role, e.g. during Late Cretaceous suturing, in addition to overthrusting. 相似文献
7.
The Blue Nile Basin, situated in the Northwestern Ethiopian Plateau, contains ∼1400 m thick Mesozoic sedimentary section underlain by Neoproterozoic basement rocks and overlain by Early–Late Oligocene and Quaternary volcanic rocks. This study outlines the stratigraphic and structural evolution of the Blue Nile Basin based on field and remote sensing studies along the Gorge of the Nile. The Blue Nile Basin has evolved in three main phases: (1) pre‐sedimentation phase, include pre‐rift peneplanation of the Neoproterozoic basement rocks, possibly during Palaeozoic time; (2) sedimentation phase from Triassic to Early Cretaceous, including: (a) Triassic–Early Jurassic fluvial sedimentation (Lower Sandstone, ∼300 m thick); (b) Early Jurassic marine transgression (glauconitic sandy mudstone, ∼30 m thick); (c) Early–Middle Jurassic deepening of the basin (Lower Limestone, ∼450 m thick); (d) desiccation of the basin and deposition of Early–Middle Jurassic gypsum; (e) Middle–Late Jurassic marine transgression (Upper Limestone, ∼400 m thick); (f) Late Jurassic–Early Cretaceous basin‐uplift and marine regression (alluvial/fluvial Upper Sandstone, ∼280 m thick); (3) the post‐sedimentation phase, including Early–Late Oligocene eruption of 500–2000 m thick Lower volcanic rocks, related to the Afar Mantle Plume and emplacement of ∼300 m thick Quaternary Upper volcanic rocks. The Mesozoic to Cenozoic units were deposited during extension attributed to Triassic–Cretaceous NE–SW‐directed extension related to the Mesozoic rifting of Gondwana. The Blue Nile Basin was formed as a NW‐trending rift, within which much of the Mesozoic clastic and marine sediments were deposited. This was followed by Late Miocene NW–SE‐directed extension related to the Main Ethiopian Rift that formed NE‐trending faults, affecting Lower volcanic rocks and the upper part of the Mesozoic section. The region was subsequently affected by Quaternary E–W and NNE–SSW‐directed extensions related to oblique opening of the Main Ethiopian Rift and development of E‐trending transverse faults, as well as NE–SW‐directed extension in southern Afar (related to northeastward separation of the Arabian Plate from the African Plate) and E–W‐directed extensions in western Afar (related to the stepping of the Red Sea axis into Afar). These Quaternary stress regimes resulted in the development of N‐, ESE‐ and NW‐trending extensional structures within the Blue Nile Basin. Copyright © 2008 John Wiley & Sons, Ltd. 相似文献
8.
不同于华北克拉通东部普遍存在的NE走向断层,鲁西地块广泛发育一组特征明显的NW走向断层,包括非控盆断层和控盆断层两类。前者位于鲁西地块最南部,倾角相对较陡,错开了古生界及以下地层,下盘太古宇中发育韧性剪切带,断层碎裂岩指示断层存在多期活动;后者位于非控盆断层以北,除蒙山断层外韧性剪切带不发育,倾角相对较缓,控制了中生代以来的沉积。磷灰石/锆石裂变径迹证据分析得出NW走向断层的活动存在差异。断层上、下盘样品磷灰石裂变径迹表观年龄在在67±5~35±2Ma之间,径迹直方图表明样品在冷却过程中没有受到热扰动。通过平均径迹长度-年龄(或香蕉图)图、单颗粒峰值年龄、径迹年龄谱模式以及热史反演模拟综合分析来约束断层的活动时间,结果表明非控盆断层可能在早侏罗世约184Ma开始活动,之后在晚白垩世80~75Ma以及新生代~61Ma和51~43Ma活动,43Ma之后不再活动。控盆断层活动时间稍晚,于早白垩世约141Ma、晚白垩世80~75Ma活动,新生代活动时间为约61Ma、49~42Ma以及36~32Ma。总体上,NW走向断层由早到晚由南向北发育,非控盆断层活动时间早、结束早;控盆断层活动晚、结束晚,并控制了凹陷的向北发育。中生代以来区域构造应力场的变化和郯庐断裂带的走滑作用是导致两类NW走向断层差异演化的根本原因,在深部则受控于晚三叠世以来华北、扬子板块陆陆碰撞和古太平洋板块俯冲方向和速度的改变。印支期后挤压到伸展的转变,加上郯庐断裂带的左行走滑,使靠近华北克拉通南缘的前端NW走向断层首先发育,因倾角较大故不控制盆地发育;向北的后端相对伸展,成为控盆断层,后经早白垩世约141Ma期间的伸展、晚白垩世末80~75Ma和新生代的发育断层最终成型。NW走向断层的这种大致向北迁移的规律,隐示华北克拉通破坏可能始于早侏罗世或晚侏罗世,且由南向北逐渐拆沉。 相似文献
9.
云南楚雄盆地位于场子陆块的西南边缘,为一典型的中生代周缘前陆盆地,盆地演化阶段明显,晚三叠世为前陆早期复理石沉积,侏罗纪则为前陆晚期磨拉石沉积。对盆地构造沉降史研究后笔者认为:①晚三叠世复理石沉积盆地构造沉降幅度巨大,沉降与沉积中心位于盆地最西部,紧邻古哀牢山造山带,沉积体呈形楔形展布;③侏罗纪磨拉石沉积盆地构造沉降和沉积中心以及前缘隆起向内陆方向迁移明显;③中生代构造快速沉降的沉积体的楔形展布表 相似文献
10.
东北东部虎林盆地的构造特征、成盆机制及敦-密断裂带北东段的形成时代 总被引:2,自引:0,他引:2
虎林盆地位于黑龙江省东部,是叠置在佳木斯地块之上的中、新生代断陷-坳陷盆地,其构造变形可以划分为3个构造演化阶段:早白垩世为NW-SE向伸展作用阶段,主要形成一系列各自独立的NE向箕状断陷群;晚白垩世为NW-SE向挤压作用阶段,使部分早期控陷正断层发生反转,形成反转构造,虎林盆地转化为具有多个沉降中心的NE向挤压坳陷盆地群;古近纪-第四纪为NNW-SSE向挤压作用阶段,虎林盆地的构造格局发生了重大变化,不仅使部分早期控陷正断层发生反转作用形成大型反转构造,而且在七虎林河凹陷与中央隆起之间形成NEE向大型逆冲断层(敦-密断裂)和断层传播褶皱,它们共同控制了盆地的形成和沉积作用,虎林盆地转化为具有1个中央隆起和南、北2个坳陷的NEE向挤压坳陷型盆地。东北地区自白垩纪以来始终处于活动大陆边缘的大地构造背景,包括虎林盆地在内的东北东部盆地群的形成与伊泽纳奇板块、太平洋板块向欧亚板块的俯冲作用有关。敦-密断裂带总体上呈NE向展布,具有左行走滑的性质,在靠近虎林盆地的北东段转变为NEE向展布,断层的性质也转变为逆冲断层,敦-密断裂带北东段的逆冲作用很可能与该断裂带的NE向左行走滑作用在NEE向的转换挤压有关。敦-密断裂带自古近纪始新世-渐新世虎林期开始活动,一直持续活动到第四纪。 相似文献
11.
The Qinling Orogenic belt has been well documented that it was formed by multiple steps of convergence and subsequent collision between the North China and South China Blocks during Paleozoic and Late Triassic times. Following the collision in Late Triassic times, the whole range evolved into an intracontinental tectonic process. The geological, geophysical and geochronological data suggest that the intracontinental tectonic evolutionary history of the Qinling Orogenic Belt allow deduce three stages including strike-slip faulting during Early Jurrassic, N-S compressional deformation during Late Jurassic to Early Cretaceous and orogenic collapse during Late Cretaceous to Paleogene. The strike-slip faulting and the infills in Early Jurassic along some major boundary faults show flower structures and pull-apart basins, related to the continued compression after Late Triassic collision between the South Qinling Belt and the South China Block along the Mianlue suture. Late Jurassic to Early Cretaceous large scale of N-S compression and overthrusting progressed outwards from inner of Qinling Orogen to the North China Block and South China Block, due to the renewed southward intracontinental subduction of the North China Block beneath the Qinling Orogenic Belt and continuously northward subduction of the South China Block, respectively. After the Late Jurassic-Early Cretaceous compression and denudation, the Qinling Orogenic Belt evolved into Late Cretaceous to Paleogene orogen collapse and depression, and formed many large fault basins along the major faults. 相似文献
12.
大别造山带发育了与大陆俯冲-折返和碰撞造山等相关的不同构造岩石单位.针对存在的问题,本项研究开展了宿松变质带、中大别超高压带和北大别杂岩带等不同俯冲岩片花岗质岩石的野外地质调查以及岩石学、元素-同位素地球化学和锆石年代学等方面系统研究.研究结果表明:(1)宿松变质带花岗片麻岩的原岩时代包括晚太古代(2.5~2.7 Ga)和新元古代(770~830 Ma)两大类,其中新元古代花岗片麻岩的原岩是由经历了~2.0 Ga变质作用的晚太古代岩石在新元古代大陆裂解过程中发生重熔作用形成的;(2)首次揭示中大别花岗片麻岩至少包含两种不同的原岩时代(~750 Ma和780~800 Ma)与岩石成因,并在三叠纪俯冲-折返期间经历了~230 Ma和~220 Ma两期部分熔融作用;(3)北大别混合岩中发育折返早期(209±2 Ma)因高温减压而引起的黑云母脱水熔融以及山根垮塌期间(110~145 Ma)有水加入的加热熔融(水致熔融)形成的多种浅色体;(4)发现并限定了北大别变质闪长岩是在燕山期山根垮塌期间,由三叠纪深俯冲的新元古代镁铁质下地壳岩石发生部分熔融作用而形成的.因此,这为大别造山带在新元古代大陆裂解、印支期地壳的俯冲-折返及燕山期山根垮塌期间发生的多种部分熔融作用提供了新的制约. 相似文献
13.
V. C. Thakur 《Journal of Earth System Science》1990,99(2):169-185
The Indus Tsangpo suture zone in Ladakh lies between the Phanerozoic sequence of the Zanskar Zone of Tethys Himalaya in the
south and Karakoram zone in the north. The five palaeotectonic regimes recognized in the suture zone are: The Indus palaeosubduction
complex, the Ladakh magmatic arc, the Indus arc-trench gap sedimentation, the Shyok backarc and the Post-collision molasse
sedimentation. The Ladakh magmatic arc, comprising intrusives of the Ladakh plutonic complex and extrusives of the Dras, Luzarmu
and Khardung formations, owes its origin to the subduction of the Indian oceanic plate underneath the Tibet-Karakoram block.
The Indus Formation, lower Cretaceous to middle Eocene in age, was laid down in a basin between the magmatic arc and the subduction
complex. The Shergol and Zildat ophiolitic melange belts exhibit green-schist and blue-schist facies metamorphism and show
structural geometry and deformation history dissimilar to that of the underlying and overlying formations. The melange belts
and the flysch sediments of the Nindam Formation represent a palaeosubduction complex. The Shyok suture zone consists of tectonic
slices of metamorphics of the Pangong Tso Crystallines, Cretaceous to lower Eocene volcanics and sedimentaries, together with
ultramafic and gabbro bodies and molasse sediments. This petrotectonic assemblage is interpreted as representing a back-are
basin. Post-collision molasse sedimentaries are continental deposits of Neogene age, and they occur with depositional contact
transgressing the lithological and structural boundaries. Two metamorphic belts, the Tso Morari crystalline complex and the
Pangong Tso Crystallines, flank to the south and north respectively of the Indus suture zone in Eastern Ladakh. Three generations
of fold structures and associated penetrative (and linear) structures, showing a similar deformation history of both the metamorphic
belts, are developed. The shortening structures developed as a result of collision during the postmiddle Eocene time. 相似文献
14.
陕西凤太晚古生代拉分盆地动力学与金-多金属成矿 总被引:3,自引:0,他引:3
采用沉积盆地构造-古地理位置恢复重建和构造-岩相学等新方法研究认为,凤太晚古生代沉积盆地属于受板块斜向俯冲碰撞动力学控制下的拉分盆地。在中泥盆世初期,凤太沉积盆地被周缘垂向基底隆起分隔,其成盆构造动力学主要受四组同生断层,晚古生代沉降中心和沉积中心不断发生迁移。中泥盆世中期在盆地北部形成了北西向沉降中心和沉积中心,晚泥盆世末期沉积盆地萎缩,沉降中心和沉积中心收缩于沉积盆地中心。石炭纪沉降中心和沉积中心从盆地中心迁移到盆地四周边缘的同生断裂带附近,在沉积盆地北侧边缘商丹带南侧,形成了石炭纪-早三叠世与俯冲消减带有关的楔状沉积充填体。在凤太拉分盆地中形成的近东西向、北北东向、近南北向和北西向网状同生断裂带系统共同控制了凤太泥盆纪拉分盆地形成与演化过程。其中,商丹带(西段)、礼县-凤县-凤镇-山阳同生断裂带(中段)和酒奠梁-镇安-板岩镇同生断裂带(西段)三个主控同生断裂带不但在泥盆纪期间对于凤太泥盆纪拉分盆地形成具有显著控制作用,而且石炭纪-早三叠世拉分盆地演化过程也具有十分重要的控制作用,石炭纪-早三叠世同生断裂带发生构造反转并控制了沉降中心和沉积中心。采用沉积盆地动力学和构造-岩相学等新方法研究认为,在凤太晚古生代拉分盆地具有分级特征,西部凤县二级盆地为金-多金属成矿集中区,东部太白二级盆地为金矿成矿集中区。在八方山-银母寺三级拉分盆地中,八方山和银母寺等多金属矿床与八卦庙超大型金矿床具有矿田尺度上成矿分带,主要由于三级盆地、同生断裂、热水沉积岩相和构造热流体叠加岩相控制了矿田和矿床尺度上金与多金属成矿分带。凤太拉分盆地北部和东部金矿矿源层和初步富集成矿形成主要与泥盆纪钠长岩相和钠质热水沉积岩相有关,并受钠长碳酸质角砾岩-铁白云石钠长石角砾岩等石炭纪构造-热流体岩相叠加;凤太拉分盆地南部温江寺三叠系浊积岩系中热水硅质岩相和层状英安质凝灰岩是卡林型金矿重要赋矿层位;凤太拉分盆地中部热水沉积-改造型铅锌矿主要与硅质岩相和菱铁矿铁白云岩相等热水沉积相密切有关。 相似文献
15.
《地学前缘(英文版)》2019,10(6):2287-2300
The Sulu orogenic belt (SOB) separates the North and South China blocks in East Asia and formed during Triassic continent-continent collision. However, late Mesozoic post-collisional exhumation is poorly understood due to lack of surface evidence for Paleo-Pacific subduction and associated effects. This paper interprets the tectonic history of the SOB using detrital zircon age data from Early Cretaceous sedimentary units along with previously published geochronologic and geochemical data to reconstruct sedimentological and tectonic history. Detrital zircon age distributions obtained from sedimentary units include a 2.0 Ga subpopulation that appears only in turbidite units to the southeast. This sediment probably derived from the Yangtze Block. Terrestrial facies from the Jiao-Lai basin to the northwest appear to derive from the North China Block. Geochronologic and geochemical data indicate that Early Cretaceous, post-collisional volcanism was compositionally bimodal (mafic-felsic) with associated intrusive activity that peaked at 120 Ma. Seismic images of northerly regions of the study area indicate this occurred in an extensional setting. Sedimentary facies and field structural analyses revealed an unconformity interpreted to reflect rapid uplift with NW–SE compression to the south. Given observed sinistral movement along the Tan-Lu fault, we interpret northwest and southeast regions of the SOB as experiencing transtensional and transpressional tectonics, respectively, driven by continuous subduction of the Paleo-Pacific Plate. Intrusion of the Late Yanshannian granitoids marked the final formational stage of this unique tectonic setting. 相似文献
16.
The contractional structures in the southern Ordos Basin recorded critical evidence for the interaction between Ordos Basin and Qinling Orogenic Collage. In this study, we performed apatite fission track(AFT) thermochronology to unravel the timing of thrusting and exhumation for the Laolongshan-Shengrenqiao Fault(LSF) in the southern Ordos Basin. The AFT ages from opposite sides of the LSF reveal a significant latest Triassic to Early Jurassic time-temperature discontinuity across this structure. Thermal modeling reveals at the latest Triassic to Early Jurassic, a ~50°C difference in temperature between opposite sides of the LSF currently exposed at the surface. This discontinuity is best interpreted by an episode of thrusting and exhumation of the LSF with ~1.7 km of net vertical displacement during the latest Triassic to Early Jurassic. These results, when combined with earlier thermochronological studies, stratigraphic contact relationship and tectono-sedimentary evolution, suggest that the southern Ordos Basin experienced coeval intense tectonic contraction and developed a north-vergent fold-and-thrust belt. Moreover, the southern Ordos Basin experienced a multi-stage differential exhumation during Mesozoic, including the latest Triassic to Early Jurassic and Late Jurassic to earliest Cretaceous thrust-driven exhumation as well as the Late Cretaceous overall exhumation. Specifically, the two thrust-driven exhumation events were related to tectonic stress propagation derived from the latest Triassic to Early Jurassic continued compression from Qinling Orogenic Collage and the Late Jurassic to earliest Cretaceous intracontinental orogeny of Qinling Orogenic Collage, respectively. By contrast, the Late Cretaceous overall exhumation event was related to the collision of an exotic terrain with the eastern margin of continental China at ~100 Ma. 相似文献
17.
华南中生代大地构造研究新进展 总被引:33,自引:0,他引:33
华南地区中生代构造动力体制经历了从特提斯构造域向滨太平洋构造域的转换,由此产生了强烈的陆内造山作用和岩浆活动,形成了复杂构造组合的晚中生代陆内造山带和火成岩省。本项研究在下列几个方面取得了新的进展:(1)通过对雪峰山地区沅麻盆地的野外调查和构造测量,确定了该盆地晚中生代-早新生代5期构造应力场及其演替序列:中晚侏罗世近W—E向挤压、早白垩世NW—SE向伸展、早白垩世中晚期NW—SE向挤压、晚白垩世近N—S向伸展、古近纪晚期NE—SW向挤压。构造应力场方向的变化记录了不同板缘的动力作用对该区的影响。(2)识别了湖南地区晚古生代-早中生代海相地层中发育的横跨叠加褶皱构造,并基于地层接触关系和已有火成岩同位素年代学数据分析,认为该地区横跨叠加褶皱构造记录了中生代两期构造挤压和地壳增厚事件:早期近东西向褶皱构造是对三叠纪华南地块南北边缘大陆碰撞和增生作用的远程响应,晚期NE—NNE向褶皱构造则是对中晚侏罗世古太平洋板块向华南大陆之下低角度俯冲作用的变形响应。(3)对湖南衡山西缘拆离断裂带的变形结构和运动学特征进行了详细的调查和构造测量,确定了衡山变质核杂岩构造,并对拆离带中韧性剪切变形的钠长岩脉的锆石进行了SHRIMP U-Pb测年,从而确定了华南地区伸展构造的起始时代约137 Ma,即早白垩世早中期。(4)通过锆石U-Pb年代学测试分析,揭示了东南沿海长乐—南澳构造带早白垩世2期构造-岩浆事件:早期(147~135 Ma)表现为强烈的混合岩化作用和深熔作用形成的片麻状花岗岩、花岗片麻岩等;晚期(135~117 Ma)岩浆岩以含石榴子石花岗岩为主。这个结果表明东南沿海构造带是晚中生代陆缘造山带,造山作用可能起始于晚侏罗世,于早白垩世早中期(135 Ma)以来发生伸展垮塌。在上述研究结果的基础上,探讨了华南地区三叠纪"印支运动"和中、晚侏罗世"燕山运动"的表现及其产生的板块构造动力体制及其转换时代、早白垩世从挤压构造应力体制向伸展构造应力体制转变的时间节点。 相似文献
18.
M. Tischler H. R. Gröger B. Fügenschuh S. M. Schmid 《International Journal of Earth Sciences》2007,96(3):473-496
The interplay between the emplacement of crustal blocks (e.g. “ALCAPA”, “Tisza”, “Dacia”) and subduction retreat is a key
issue for understanding the Miocene tectonic history of the Carpathians. Coeval thrusting and basin formation is linked by
transfer zones, such as the Mid-Hungarian fault zone, which seperates ALCAPA from Tisza-Dacia. The presented study provides
new kinematic data from this transfer zone. Early Burdigalian (20.5 to ∼18.5 Ma) SE-directed thrusting of the easternmost
tip of ALCAPA (Pienides), over Tisza-Dacia is linked to movements along the Mid-Hungarian fault zone and the Periadriatic
line, accommodating the lateral extrusion of ALCAPA. Minor Late Burdigalian (∼18.5 to 16 Ma) NE-SW extension is interpreted
as related to back-arc extension. Post Burdigalian (post-16 Ma) NE–SW shortening and NW–SE extension correlate with “soft
collision” of Tisza-Dacia with the European foreland coupled with southward migration of active subduction. During this stage
the Bogdan-Voda and Dragos-Voda faults were kinematically linked to the Mid-Hungarian fault zone. Sinistral transpression
(16 to 12 Ma) at the Bogdan-Voda fault was followed by sinistral transtension (12–10 Ma) along the coupled Bogdan-Dragos-Voda
fault system. During the transtensional stage left-lateral offset was reduced eastwards by SW trending normal faults, the
fault system finally terminating in an extensional horse-tail splay. 相似文献
19.
杨宗让 《沉积与特提斯地质》2002,22(3):53-59
地处柴南缘昆中蛇绿杂岩带与羌塘地块北缘可可西里—金沙江古缝合线之间的松潘—甘孜褶皱带(包括东昆仑构造带),其主体应属古特提斯洋晚石炭世一晚三叠世时期向其北侧的柴达木古陆南缘俯冲过程中在活动陆缘弧—沟间隙之间增生形成的一个大型弧前构造带。具有由弧前盆地沉积楔和基底增生杂岩构成的双重结构特点,其形成与冈瓦纳大陆北缘若尔盖“三角”地块的楔入及俯冲带向南迁移有关。大致经历了晚石炭世一早三叠世狭窄弧前盆地和中晚三叠世宽阔弧前盆地两个主要演化阶段。 相似文献
20.
远离活动板块边缘的四川盆地以其周缘复杂分布的褶皱构造带而著称,这些构造带的成因及其大地构造背景一直是华南大地构造研究的焦点之一。本文基于区域构造编图、褶皱构造样式和叠加变形分析,论述了四川盆地及其周缘中生代挤压变形特征及其定型时代,确定了重要构造事件及其产生的构造样式。研究显示,四川盆地及其周缘地带中生代经历了3个重大构造事件,每个构造事件产生的构造形迹在空间上发生复合和联合,造就了四川盆地及其周缘复杂的构造组合样式。中晚三叠世碰撞造山事件(印支运动)在扬子地区形成近W-E向褶皱构造,扬子地块西缘伴随着松潘—甘孜褶皱造山带的形成,发育了龙门山—锦屏山逆冲-推覆构造带及川滇前陆盆地,奠定了川—渝—黔—滇大型沉积盆地,构成四川盆地的原形。中晚侏罗世时期(燕山早幕),东亚构造体制发生重大变革,来自北部、东部、西部和南部的板块多向汇聚导致了大陆多向汇聚构造体系的形成和发展,其中秦岭造山带的再生活动导致南部米仓山—大巴山前陆构造带的形成和发展;来自太平洋板块向西推挤,导致了川东地区NW向突出的弧型构造和川南华蓥山帚状构造的形成;羌塘地块的向东侧向挤出,在扬子地块西北缘发生褶皱逆冲变形(龙门山—锦屏山构造带)。这期多向挤压事件强烈改造了四川T3-J1-2原形盆地,周缘褶皱构造带基本定型。早白垩世晚期的挤压事件(燕山晚幕)进一步改造了四川盆地,NW-SE向构造得到加强。除了西缘以外,四川盆地其他周缘褶皱构造带主体定型于晚侏罗世的陆内造山作用阶段,是扬子克拉通周边造山带在周邻板块多向汇聚作用下引发的再生复活的结果,成为中国东部陆内汇聚构造体系的重要组成部分。 相似文献