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1.
天山-阿尔泰地区古生代构造及相关的内生成矿作用 总被引:1,自引:0,他引:1
探讨天山-阿尔泰地区大地构造及其相关的内生成矿作用是一个重要而又有趣的研究课题.阿尔泰地区属于早古生代碰撞带,天山地区属于晚古生代早期(晚泥盆世一早石炭世)碰撞带,均为区域性近南北向缩短-碰撞作用的结果.在晚泥盆世一早石炭世,阿尔泰地区近NW向区域性断层呈现右行走滑的特征,天山地区近EW向的区域性断层表现为逆断层的活动.但在晚石炭世一早二叠世,受乌拉尔碰撞带挤压作用远程效应的影响,该地区受到较弱的向东挤压的作用,阿尔泰地区NW向断层转变成左行走滑断层,天山地区近EW向断层则转变为右行走滑断层,使该区岩石发生适度的破碎,以致形成大量世界著名的内生金属矿床.对于亚洲大陆来说,碰撞作用最强烈的时期并不一定是内生金属成矿作用最有利的阶段,应该审慎地对待所谓的“造山带成矿作用假说”.最后,笔者还对该区深部隐伏内生金属矿床的找寻提出了一些建议. 相似文献
2.
The Verkhoyansk–Kolyma belt (VK) forms the western part of the Verkhoyansk–Chukotka Mesozoic orogen (NE Asia) and lies between the Siberian craton on the western side, the Mesozoic–Cenozoic Koryak–Kamchatka accretionary orogen on the eastern side, and the Arctic Alaskan craton to the north. The VK results from the collision of the Siberian craton and the Kolyma–Omolon composite terrane (KO), which acted as an indentor resulting the Kolyma orocline. The KO is made up of ophiolite and olistostromal and schistose units that were amalgamated during the Middle–Late Jurassic by thrust and nappe tectonics under greenschist facies metamorphism. This was followed in Latest Jurassic by thrusting and strike-slip faulting related to the collision of the KO composite terrane with the Siberian craton. This collision also produced the Verkhoyansk fold-and-thrust belt in the Siberian continental margin. In the earliest Cretaceous, collision of the Alaskan and Siberian margins resulted in further thrust and strike-slip tectonism. 相似文献
3.
大兴安岭地区上古生界变形特征及构造层划分 总被引:4,自引:0,他引:4
大兴安岭地区古生界构造变形表明,上古生界自二叠纪末以来遭受了3期构造变形改造:第一期变形为二叠纪末华北板块与佳蒙地块碰撞造成的近EW向展布的断裂和褶皱构造,强度由南向北有减弱的趋势;第二期变形为侏罗纪西太平洋板块俯冲导致的NE—NNE向左行走滑断裂和褶皱构造;第三期为NW向具有右行走滑特征的断裂构造,时间大致在晚侏罗世—早白垩世。综合区域构造、沉积岩古地理分析对比,初步将大兴安岭地区上古生界划分为早古生代、D—C1、C2—P2、P3—T14个构造层:早古生代末加里东运动之后,在D—C1期间早期以伸展为主,总体表现为北海南陆的古地理特征;早石炭世末期松嫩地块与额尔古纳—兴安地块沿嫩江—扎兰屯一线碰撞拼接;C2—P2期间总体表现为造山后伸展特征,表现为北陆南海;P3—T1时期古亚洲洋的闭合,海水退出,转为陆相。 相似文献
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5.
Dmitriy V. Alexeiev Harry E. Cook Vasiliy M. Buvtyshkin Lyudmila Y. Golub 《Comptes Rendus Geoscience》2009,341(2-3):287-297
The deformation history of the Late Palaeozoic Ural–Tian Shan junction is discussed for the example of the Karatau ridge in southern Kazakhstan. Three deformation events are recognized. The Late Carboniferous D1 event is characterized by Laramide-style thrust-and-fold structures on the southern margin of Kazakhstan with shortening in a NE–SW direction. The Latest Permian and Triassic D2 event is controlled by compression in an east–west direction, which reflects collisional deformation in the Urals. The main structures are submeridional folds and north–west-striking sinistral strike–slip faults. The Triassic D3 event with shortening in a north–south direction reflects collision of the Turan microcontinent against the southern margin of Kazakhstan. The main structures are north–west-striking dextral strike–slip faults. Our new data provides important clues for the reconstruction of pre-Cretaceous structures between the Urals and the Tian Shan. 相似文献
6.
鹤庆–洱源断裂带是滇西北活动断裂系的重要组成部分,对其性质、特征和活动历史的研究可为区域地震活动评价和震害防御提供依据,也可为青藏高原东南缘构造变形特征、历史和方式提供基础数据。通过对鹤庆–洱源断裂带中段基岩山区的室内外调查和研究,结合光释光和14C 定年,初步查明该段断裂具有复杂的空间展布格局,由多条左旋走滑性质的分支断裂构成,它们共同吸收了断裂带在鹤庆盆地南端与洱源盆地北端之间的走滑分量;运动性质以左旋走滑为主,局部地段兼具正断或逆冲性质;剖面地层断错和覆盖关系表明该段断裂在晚更新世活动强烈,现有证据表明最新活动时代约为距今2万年。结合区域构造环境,作者认为鹤庆–洱源断裂带中段晚更新世以来的活动是对青藏高原强烈隆升的响应,其左旋走滑符合滇中次级块体顺时针转动模型,是块体旋转在角端的局部应变响应。 相似文献
7.
《Geodinamica Acta》2001,14(1-3):177-195
The east Anatolian plateau and the Lesser Caucasus are characterised and shaped by three major structures: (1) NW- and NE-trending dextral to sinistral active strike-slip faults, (2) N-S to NNW-trending fissures and /or Plio-Quaternary volcanoes, and (3) a 5-km thick, undeformed Plio-Quaternary continental volcano-sedimentary sequence accumulated in various strike-slip basins. In contrast to the situation in the east Anatolian plateau and the Lesser Caucasus, the Transcaucasus and the Great Caucasus are characterised by WNW-trending active thrust to reverse faults, folds, and 6-km thick, undeformed (except for the fault-bounded basin margins) continuous Oligocene-Quaternary molassic sequence accumulated in actively developing ramp basins. Hence, the neotectonic regime in the Great Caucasus and the Transcaucasus is compressional–contractional, and Oligocene-Quaternary in age; whereas it is compressional–extensional, and Plio-Quaternary in age in the east Anatolian plateau and the Lesser Caucasus.Middle and Upper Miocene volcano-sedimentary sequences are folded and thrust-to-reverse-faulted as a result of compressional–contractional tectonic regime accompanied by mostly calc-alkaline volcanic activity, whereas Middle Pliocene-Quaternary sequences, which rest with angular unconformity on the pre-Middle Pliocene rocks, are nearly flat-lying and dominated by strike-slip faulting accompanied by mostly alkali volcanic activity implying an inversion in tectonic regime. The strike-slip faults cut and displace dykes, reverse to thrust faults and fold axes of Late Miocene age up to maximum 7 km: hence these faults are younger than Late Miocene, i.e., these formed after Late Miocene. Therefore, the time period between late Serravalian (∼ 12 Ma) continent–continent collision of Arabian and Eurasian plates and the late Early Pliocene inversion in both the tectonic regime, basin type and deformation pattern (from folding and thrusting to strike-slip faulting) is here termed as the Transitional period.Orientation patterns of various neotectonic structures and focal mechanism solutions of recent earthquakes that occurred in the east Anatolian plateau and the Caucasus fit well with the N–S directed intracontinental convergence between the Arabian plate in the south and the Eurasian plate in the north lasting since Late Miocene or Early Pliocene in places. 相似文献
8.
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
9.
The northern China–Mongolia tract exhibited a tectonic transition from contractional to extensional deformation in late Mesozoic time. Late Middle to early Late Jurassic crustal shortening is widely thought to have resulted from collision of an amalgamated North China–Mongolia block and the Siberian plate, but widespread late Late Jurassic–Early Cretaceous extension has not been satisfactorily explained by existing models. Some prominent features of the extensional tectonics of the northern China–Mongolia tract are: (1) Late Jurassic voluminous volcanism prior to Early Cretaceous large-magnitude rapid extension; (2) overlapping in time of contractional deformation in the Yinshan–Yanshan belt with development of extension-related basins in the interior of the northern China–Mongolia tract; and (3) widespread occurrence of alkali granitic plutonism, extensional basins and metamorphic core complexes in the Early Cretaceous. A new explanation is advanced in this study for this sequence of events. The collision of amalgamated North China–Mongolia with Siberia led to crustal overthickening of the northern China–Mongolia tract and formation of a high-standing plateau. Subsequent breakoff at depth of the north-dipping Mongol–Okhotsk oceanic slab is suggested as the main trigger for late Mesozoic lithospheric extension of that tract. Slab breakoff resulted in mantle lithospheric stretching of the adjacent northern China–Mongolia tract with subsequent ascent of hot asthenosphere and magmatic underplating at the base of the crust. Collectively, these phenomena triggered gravitational collapse of the previously thickened crust, leading to late Late Jurassic–Early Cretaceous crustal extension, and importantly, coeval contraction along the southern margin of the plateau in the Yinshan–Yanshan belt. The proposed model provides a framework for interpreting the spatial and temporal relationships of distinct processes and reconciling some seemingly contradictory phenomena, such as the synchronous extension of northerly terranes during major contraction in the neighboring Yanshan–Yinshan belt. 相似文献
10.
北极地区地质构造及主要构造事件 总被引:1,自引:0,他引:1
北极地区范围很广,北极圈面积达2 100×104 km2,区域地质复杂。通过对北极地区区域地质编图,笔者认为前寒武纪主要由波罗的、劳伦和西伯利亚三大克拉通,以及其间的微板块或地块组成。主要造山带包括新元古代-早寒武世的贝加尔造山带、晚志留世-早石炭世的加里东造山带、晚古生代-早中生代的海西造山带、晚中生代的上扬斯克造山带、新西伯利亚造山带与楚科奇-布鲁克斯造山带。根据北极地区区域地质构造特征,显生宙以来经历的构造事件大致包括:新元古代-早寒武世的贝加尔运动,致使波罗的古陆与斯瓦尔巴-喀拉地块碰撞造山;晚泥盆世-早石炭世的加里东运动,在劳伦古陆周边形成规模巨大的加里东造山带;晚古生代的海西运动,波罗的古陆与西伯利亚古陆的碰撞造山形成海西造山带;北极阿拉斯加-楚科奇微板块裂离加拿大边缘,侏罗纪加拿大海盆开始张开;早白垩世,阿拉斯加-楚科奇微板块继续与西伯利亚碰撞,阿纽伊洋(Anyui Ocean)消亡,形成上扬斯克-布鲁克斯造山带。受北极调查程度影响,许多问题有待进一步研究。 相似文献
11.
Architecture and mineral deposit settings of the Altaid orogenic collage: a revised model 总被引:19,自引:0,他引:19
Alexander Yakubchuk 《Journal of Asian Earth Sciences》2004,23(5):761
The Altaids are an orogenic collage of Neoproterozoic–Paleozoic rocks located in the center of Eurasia. This collage consists of only three oroclinally bent Neoproterozoic–Early Paleozoic magmatic arcs (Kipchak, Tuva–Mongol, and Mugodzhar–Rudny Altai), separated by sutures of their former backarc basins, which were stitched by new generations of overlapping magmatic arcs. In addition, the Altaids host accreted fragments of the Neoproterozoic to Early Paleozoic oceanic island chains and Neoproterozoic to Cenozoic plume-related magmatic rocks superimposed on the accreted fragments. All these assemblages host important, many world-class, Late Proterozoic to Early Mesozoic gold, copper–molybdenum, lead–zinc, nickel and other deposits of various types.In the Late Proterozoic, during breakup of the supercontinent Rodinia, the Kipchak and Tuva–Mongol magmatic arcs were rifted off Eastern Europe–Siberia and Laurentia to produce oceanic backarc basins. In the Late Ordovician, the Siberian craton began its clockwise rotation with respect to Eastern Europe and this coincides with the beginning of formation of the Mugodzhar–Rudny Altai arc behind the Kipchak arc. These earlier arcs produced mostly Cu–Pb–Zn VMS deposits, although some important intrusion-related orogenic Au deposits formed during arc–arc collision events in the Middle Cambrian and Late Ordovician.The clockwise rotation of Siberia continued through the Paleozoic until the Early Permian producing several episodes of oroclinal bending, strike–slip duplication and reorganization of the magmatic arcs to produce the overlapping Kazakh–Mongol and Zharma-Saur–Valerianov–Beltau-Kurama arcs that welded the extinct Kipchak and Tuva–Mongol arcs. This resulted in amalgamation of the western portion of the Altaid orogenic collage in the Late Paleozoic. Its eastern portion amalgamated only in the early Mesozoic and was overlapped by the Transbaikal magmatic arc, which developed in response to subduction of the oceanic crust of the Paleo-Pacific Ocean. Several world-class Cu–(Mo)-porphyry, Cu–Pb–Zn VMS and intrusion-related Au mineral camps, which formed in the Altaids at this stage, coincided with the episodes of plate reorganization and oroclinal bending of magmatic arcs. Major Pb–Zn and Cu sedimentary rock-hosted deposits of Kazakhstan and Central Asia formed in backarc rifts, which developed on the earlier amalgamated fragments. Major orogenic gold deposits are intrusion-related deposits, often occurring within black shale-bearing sutured backarc basins with oceanic crust.After amalgamation of the western Altaids, this part of the collage and adjacent cratons were affected by the Siberian superplume, which ascended at the Permian–Triassic transition. This plume-related magmatism produced various deposits, such as famous Ni–Cu–PGE deposits of Norilsk in the northwest of the Siberian craton.In the early Mesozoic, the eastern Altaids were oroclinally bent together with the overlapping Transbaikal magmatic arc in response to the northward migration and anti-clockwise rotation of the North China craton. The following collision of the eastern portion of the Altaid collage with the Siberian craton formed the Mongol–Okhotsk suture zone, which still links the accretionary wedges of central Mongolia and Circum-Pacific belts. In the late Mesozoic, a system of continent-scale conjugate northwest-trending and northeast-trending strike–slip faults developed in response to the southward propagation of the Siberian craton with subsequent post-mineral offset of some metallogenic belts for as much as 70–400 km, possibly in response to spreading in the Canadian basin. India–Asia collision rejuvenated some of these faults and generated a system of impact rifts. 相似文献
12.
西秦岭勉略带陆内构造变形研究 总被引:12,自引:3,他引:9
秦岭造山带勉略缝合带是古特提斯洋盆向北俯冲形成的华北与华南最后拼接带。这个主缝合带俯冲-碰撞过程中以由北向南的一系列韧性逆冲推覆构造为特征,形成由前泥盆系、泥盆-石炭系和蛇绿混杂岩等不同构造岩片叠置的复杂构造带,碰撞时代从245Ma一直延续到230Ma左右。最近,作者对勉略缝合带内发育的韧性和脆性左行走滑剪切变形进行了研究,结果表明这些顺造山带的左行韧性走滑剪切变形带的变形时代为223±2Ma,与碰撞后花岗岩所确定的碰撞后构造环境的起始时间(225Ma)一致,显示这些韧性走滑剪切变形带是勉略带陆内变形初期变形产物。亦即华北、扬子大陆碰撞之后很快就转入陆内变形阶段,并且是以顺造山带的侧向走滑位移为主要变形方式。勉略带内顺造山带的脆性左行走滑断层的发育,表明这种顺造山带的侧向位移过程从深部到地壳浅层是一致的。因此,大陆碰撞在直接碰撞之后很快转变为顺造山带的侧向走滑位移为主的陆内变形,这种位移可能表现为两个大陆碰撞后的相对走滑,或是碰撞带中强烈变形部分顺造山带的侧向挤出,从而消减了正向碰撞所造成的地壳缩短和增厚。 相似文献
13.
从郯庐断裂带两侧的“盆”“山”耦合演化
看前白垩纪“郯庐断裂带”的性质 总被引:9,自引:1,他引:8
郯庐断裂带的前身是3条重要的边界断裂(古郯庐断裂、辽渤断裂和敦化-密山断裂),因而前白垩纪其两侧的“盆”“山”发育分属不同的造山动力学和成盆动力学系统。其西.扬子微大陆与华北微大陆之间的秦岭-大别造山带是印支期的碰撞造山带,兴-蒙造山带是海西期的阿尔泰型(增生弧型)造山带,燕山运动时两者都成为陆内造山带。“郯庐断裂带”以东,苏鲁造山带是苏皖地块与胶辽微大陆之间的燕山期碰撞造山带,延吉-清津造山带是胶辽微大陆与兴凯地块之间的印支期碰撞造山带;更北则是由一系列外来地体沿敦化-密山断裂拼贴在西伯利亚次大陆之上而形成的斜向汇聚-剪切造山带(属板间造山带)。在此基础上,分为海西-印支期、侏罗纪和白垩纪3个时代,详细剖析了“郯庐断裂带”两侧与上述造山作用耦合的典型的磨拉石盆地和火山岩盆地的演化及其对比,证实前白垩纪“郯庐断裂带”两侧的盆地各有其独立的发育史,不是被郯庐断裂带左行平移错断的同一个盆地。对“郯庐断裂带”两侧古生代-三叠纪陆表海的研究进一步证实其西的扬子微大陆、华北微大陆、布列亚-佳木斯地块与其东的苏皖地块、胶辽微大陆、兴凯地块曾分属独立的构造单元。早白垩世时,随着新特提斯洋的部分闭合,亚洲大陆的雏形出现,上述3条边界断裂连接成郯庐断裂带并成为陆内的左行走滑断层。 相似文献
14.
陕西凤太矿集区多金属成矿作用的构造控制 总被引:3,自引:0,他引:3
陕西凤县-太白(简称凤太)矿集区铅、锌、金、银、铜多金属资源丰富,已发现二十余个大中小型矿床。在大地构造位置上,凤太矿集区位于南秦岭造山带北缘,紧邻商丹缝合带。以往的工作缺乏对矿集区整体的构造研究,本次工作通过比较系统的构造测量和解析,提出在南秦岭晚三叠世碰撞造山过程中,凤太矿集区南北两条边界断裂带的左行走滑运动导致在区内衍生了NNE向主压应力场,从而形成了NWW向复式褶皱、脆韧性剪切带、断裂和节理(纵向破裂)、B型线理,以及NNE向断裂和节理(横向破裂)、劈理、张裂隙等一系列构造组合,所有构造形迹都是在统一构造应力场下随着构造层次不断抬升,脆韧性和脆性递进变形叠加的产物,共同构成了一个大型压扭性走滑双重构造变形系统。在构造几何学上,凤太矿集区整体上表现为一个隔档式复式褶皱,由一组NWW向紧闭复背斜和一组相对宽缓复向斜组成。区内的多金属成矿作用、岩浆活动、动力变质变形作用的同位素年龄数据集中于230~190Ma。综合地质演化和成矿作用的研究成果,提出在南秦岭碰撞造山过程中引发的动力变质变形作用和岩浆活动提供了成矿元素和成矿流体,在温压梯度以及浮力效应的驱动下向上运移至走滑双重构造变形系统中的有利扩容空间中发生充填型和交代型矿化,即凤太矿集区多金属矿床是区域大规模变形变质-岩浆活动-流体作用的产物,是在构造作用这一主导因素控制下形成的一个多金属后生热液成矿系统。 相似文献
15.
大陆碰撞造山样式与过程:来自特提斯碰撞造山带的实例 总被引:2,自引:0,他引:2
本文选取特提斯域内比利牛斯、阿尔卑斯、扎格罗斯、喜马拉雅-青藏高原四个地球上最年轻的陆-陆碰撞造山带,对其造山带结构、类型、物质组成、构造岩浆过程等方面进行详细介绍,进而讨论各个造山带的差异性及其缘由,分析碰撞造山普遍性规律。资料分析表明,四个碰撞造山带具有不同的结构和组成。根据板块汇聚方向与造山带边界间的夹角可将造山带分为正向和斜向两种;根据造山带结构可将碰撞带分为对称式和不对称式两种。由此本文将碰撞造山带划分为四种基本式样:正向对称式、正向不对称式、斜向对称式、斜向不对称式,分别以比利牛斯、青藏高原、阿尔卑斯和扎格罗斯碰撞带为代表。综合分析四个造山带碰撞以来的岩浆构造活动,本文发现完整的碰撞过程可以划分为三个阶段,第一阶段主要发生挤压缩短、地壳加厚,高压变质和钙碱性火山岩浆活动;第二阶段以大规模走滑系统发育和高钾钙碱性或钾质火山岩浆作用为特征;第三个阶段挤压应力向碰撞带两侧扩展,同时伴有大型伸展构造系统的发育。在这三阶段演化历程中,比利牛斯只进行到第一阶段,成为幼年夭折的碰撞带;扎格罗斯进行到第二阶段,出现调节挤压应变的走滑系统和钾质超钾质岩浆活动;青藏高原和阿尔卑斯进行到第三个阶段,以发育大型伸展构造和钾质、超钾质岩浆活动为特征,但后者在造山带物质组成和汇聚速率方面显示出比前者更成熟的造山演化程度。因此认为岩石圈组成是碰撞造山带结构的主要控制因素,如果上覆板块具有相对不稳定的岩石圈,会使得碰撞带后陆发育宽广的构造岩浆带,造成造山带呈不对称式结构。 相似文献
16.
The Liupanshan Arcuate Tectonic Belt (LATB) is located at the northeastern margin of the Qinghai–Tibet Plateau. Major strike-slip and thrust faults in the Liupanshan area are prominent Cenozoic structures, which are critical in understanding and reconstructing the tectonic deformation history. This paper not only provides detailed investigations on geometric and kinematic characteristics of these faults in the LATB, but also dates the faults’ movements by electron spin resonance (ESR). The LATB underwent a succession of compression, extension and again compression tectonic deformation processes since the Cenozoic. The Liupanshan Curved Faults first experienced sinistral strike-slip shear during 57–61 Ma. The Liupanshan Curved Faults responded to the deformation caused by the eastward escape of the Qinghai–Tibet Plateau and acted as the northeastern boundary of the deformation. Timing for the formation of the Liupanshan Curved Faults shows that the collision of the Indian and Eurasian plates must have occurred earlier than these faults’ activity because the latter is reflected the far-field effect of the collision. 相似文献
17.
Kirk McIntosh Yosio Nakamura T.-K. Wang R.-C. Shih Allen Chen C.-S. Liu 《Tectonophysics》2005,401(1-2):23-54
We have used combined onshore and offshore wide-angle seismic data sets to model the velocity structure of the Taiwan arc–continent collision along three cross-island transects. Although Taiwan is well known as a collisional orogen, relatively few data have been collected that reveal the deeper structure resulting from this lithospheric-scale process. Our southern transect crosses the Hengchun Peninsula of southernmost Taiwan and demonstrates characteristics of incipient collision. Here, 11-km-thick, transitional crust of the Eurasian plate (EUP) subducts beneath a large, rapidly growing accretionary prism. This prism also overrides the N. Luzon forearc to the east as it grows. Just west of the arc axis there is an abrupt discontinuity in the forearc velocity structure. Because this break is accompanied by intense seismicity, we interpret that the forearc block is being detached from the N. Luzon arc and Philippine Sea plate (PSP) at this point. Our middle transect illustrates the structure of the developing collision. Steep and overturned velocity contours indicate probable large-scale thrust boundaries across the orogen. The leading edge of the coherent PSP appears to extend to beneath the east coast of Taiwan. Deformation of the PSP is largely limited to the remnant N. Luzon arc with no evidence of crustal thickening to the east in the Huatung basin. Our northern transect illustrates slab–continent collision—the continuing collision of the PSP and EUP as the PSP subducts. The collisional contact is below 20 km depths along this transect NE of Hualien. This transect shows elements of the transition from arc–continent collision to Ryukyu arc subduction. Both of our models across the Central Range suggest that the Paleozoic to Mesozoic basement rocks there may have been emplaced as thick, coherent thrust sheets. This suggests a process of partial continental subduction followed by intra-crustal detachment and buoyancy-aided exhumation. Although our models provide previously unknown structural information about the Taiwan orogen, our data do not define the deepest orogenic structure nor the structure of western Taiwan. Additional seismic (active and passive), geologic, and geodynamic modeling work must be done to fully define the structure, the active deformation zones, and the key geodynamic process of the Taiwan arc–continent collision. 相似文献
18.
青藏高原东北缘的地质地貌特征与基本构造格架受阿尔金左行走滑断裂、东昆仑左行走滑断裂和海源左行走滑断裂控制,在青藏高原的碰撞造山过程中地震作用贯穿始终.2011至2012年,作者对青藏高原东北缘东起靖远(海原断裂东段)西至昌马盆地(阿尔金断裂东南)的软沉积物变形(震积岩)进行的系统调研表明,青藏高原东北缘祁连山地区从三叠纪至第四纪各时代(侏罗纪以外)的地层中,均发现丰富的古地震纪录(震积岩).代表性震积岩发现点和层位有:靖远宝积山上三叠统、靖远糜滩乡下白垩统、昌马盆地下白垩统以及赤金堡和酒泉磁窑口附近的第四系.主要的震积岩类型有:液化脉、负载、球-枕构造、液化卷曲、层间微断裂等.根据区域地质资料分析,这些震积岩均分布于区域性大断裂附近.本文简单讨论了主要震积岩发现点与其相邻的区域构造(地震)活动之间的关系,根据靖远附近上三叠统普遍发育震积岩,提出海原断裂带的初始活动时间很可能就在晚三叠世,与青藏高原东缘龙门山地区印支期的造山地震同时期. 相似文献
19.
西准噶尔达拉布特断裂带中段晚古生代构造分析 总被引:2,自引:0,他引:2
走滑断裂构造在中亚造山带增生及演化过程的研究中扮演了重要角色,其主要构造单元均被走滑断裂带所分割。西准噶尔造山带是中亚增生型造山带的重要组成部分,达拉布特断裂是西准噶尔造山带中一条重要的走滑断裂,其复杂的构造表现吸引了大量研究者的关注。前人不仅在其构造解释上存在着走滑断层、逆冲断层或压扭性断层等诸多争议,且在其活动时代问题上也有不同的看法。本文依据在达拉布特断裂带中段开展的详细野外构造学工作,结合前人针对该地区石炭纪火山岩、浊积岩和造山后花岗岩侵入体所做的同位素年代学工作成果,对达拉布特断裂的活动性质和活动时代进行了讨论。结果确认在中二叠统沉积之前,达拉布特断裂带存在两期变形事件,分别对应于320Ma左右沿NE-SW的较深层次的左行走滑事件D1和表现为脆-韧性转换域的轴面倾向SE的褶皱作用构造事件D2。前者为主期变形事件,而后者发生在中二叠统沉积之前。本文同时报道了沿达拉布特断裂带出露右行走滑构造形迹,并讨论了其可能的成因。沿达拉布特断裂带的多期构造事件记录了西准噶尔地区造山后大规模走滑构造调整过程,是晚古生代晚期中亚各个陆块拼合后大规模陆内调整在西准噶尔造山带的具体体现。 相似文献
20.
金山金矿产于赣东北断裂带的次级剪切带中,其成矿作用与韧性剪切带的动力变质作用密切相关。本文通过对矿区金矿体的地质特征和运动学特征的分析,认为金山金矿成矿期经历了两期韧性剪切作用,即早期由NNW向SSE的韧性推覆剪切,晚期沿NE方向的左行韧性走滑剪切,分别形成NW向超糜棱岩型矿体和NE方向石英脉型矿体,两期韧剪变形均发生在新元古代,对应于江南造山带在碰撞造山阶段和后造山伸展阶段的动力变质事件。成矿后,矿区先受到NW向的挤压应力场作用,形成NE走向的逆断层、NW走向的张性断层以及SN走向的左行压扭断层,之后转为NW向的拉张应力场,形成NE走向的正断层。金山金矿床的构造变形特征指示了赣东北断裂带活动的阶段性,赣东北地区在晋宁期经历了两期构造-岩浆-变质事件;加里东-印支期构造活动比较弱;燕山期本区构造-岩浆活动强烈,引起赣东北断裂带的再次活动。 相似文献