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1.
内蒙古苏尼特左旗早白垩世宝德尔花岗岩伸展穹隆的确定及其地质意义 总被引:3,自引:1,他引:2
内蒙古宝德尔穹隆是发育在苏尼特左旗中蒙边境地区的不对称同构造伸展穹隆。该穹隆由内向外由核部早白垩世花岗岩、边缘韧性剪切带和脆性拆离断层组成,上盘为未变形的早二叠世花岗闪长岩、泥盆系片岩和早白垩世盆地,韧性剪切带和拆离断层仅发育在穹隆西南部。区域构造解析和显微构造分析表明,岩体侵位和韧性剪切带形成于同一构造应力场,指示上盘统一向NW方向剪切,变形程度由未变形的岩体核部向外侧逐渐增强,面理的形成与岩体的侵位和隆升过程密切相关。因此,该穹隆和东北亚其他岩浆穹隆相似,是不对称的花岗岩穹隆,反映了区域伸展拆离环境下侵位的同构造花岗岩穹隆的特点。 相似文献
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东秦岭松树沟蛇绿岩构造变形及其演化 总被引:1,自引:0,他引:1
东秦岭松树沟蛇绿岩是沿西沟早期韧性剪切带和界岭韧性剪切带构造侵位于早元古代秦岭群变质杂岩南缘之上的蛇绿岩推覆体,主要遭受了4期构造变形,反映蛇绿岩演化过程中四期主要的构造运动,分别为:10亿年左右上地幔部分熔融残余体──蛇绿橄榄岩块底辟侵位于上覆玄武岩、晋宁期蛇绿岩构造侵位、加里东─早华力西期由南向北的过冲及晚华力西─印支期的左行走滑运动。 相似文献
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房山变质核杂岩基底拆离断层韧性剪切变形构造及环境分析 总被引:1,自引:0,他引:1
在房山岩体南北缘出露有太古代(基底) 官地杂岩, 官地杂岩与上覆盖层不同地层之间发育一条基底韧性拆离断层.宏观及微观尺度上拆离断层运动学标志均指示SE; 剪切带内发育区域动力变质作用下的矿物组合角闪石-斜长石及硅值较高的白云母, 对其进行电子探针分析, 计算出拆离断层韧性剪切变形的温压条件为: 温度492~555 ℃, 压力0.33 Gpa左右, 达到低角闪岩相.按正常的静岩压力计算, 该韧性剪切作用发生于地表以下12.9 km左右, 代表了中地壳韧性流变的变形环境.野外观察发现房山侵入体与官地杂岩及该韧性剪切带间均呈明显的侵入接触关系, 在侵入岩体南北边缘有大量的片麻岩等捕虏体, 沿杂岩的片麻理或韧性构造面理, 发育大量的石英二长闪长岩脉, 岩脉成分与房山岩体一致, 因此该韧性剪切带的形成应早于房山岩体侵位.如对房山岩体的侵入和改造进行复原和恢复, 该韧性剪切带代表了早期的伸展作用, 可能与房山伸展穹隆体的韧性变形同期. 相似文献
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医巫闾山岩体同伸展侵位的证据及其地质意义 总被引:2,自引:0,他引:2
医巫闾山岩体是医巫闾变质核杂岩的重要组成部分。根据医巫闾山地区花岗岩变形特征及与周围构造带的相互关系,确定医巫闾山岩体为同伸展侵位的岩体,且以岩床的形式顺层侵入在医巫闾山伸展型韧性剪切带之中,修正了前人挤压环境下岩浆侵位的观点。医巫闾山岩体及尖砬子山岩体的侵位时间在160 Ma左右,表明医巫闾山地区及燕山地区中侏罗世晚期发生过强烈的地壳伸展运动,华北北部的构造体制在中侏罗世已经改变。区内中生代存在2期伸展作用:早期伸展作用发生在中侏罗世晚期,与医巫闾山岩体的侵位同期;晚期伸展作用发生在早白垩世,形成了瓦子峪拆离断层。 相似文献
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基于对辽南变质核杂岩主拆离断层及下伏韧性剪切带的几何学分析以及拆离断层带构造岩的显微构造研究,结合变质核杂岩构造—岩浆活动及其形成过程和力学机制,重点讨论了主拆离断层的波瓦状构造的特点及其形成条件。结果表明:波瓦状构造的发育与下盘晚期阶段花岗质岩体的侵位具有同时性。伸展构造发育初期就位的深成岩体加热和软化了上部地壳,此时岩石力学属性控制的钝角锯齿状断裂构成了波瓦状构造的雏形,晚期阶段花岗质深成侵入岩的不均匀侵位制约了波瓦状构造的发育。 相似文献
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衡山花岗岩体西缘韧性剪切带的特征,成因及岩体定位机制 总被引:2,自引:0,他引:2
衡山花岗岩体由南岳岩体(早期)和白石峰岩体(晚期)组成,衡山岩体西缘形成有分带明显的韧性剪切带,向西倾斜,在XZ面上呈倾向滑动剪切运动,矿物显微变形构造显示为倾向简单剪切特征。经测定,韧性剪切带形成时温度下限为343.6℃,古差应力下限为52~62MPa,应变速率下限为2.05×10~(-14)/s-3.13×10~(-14)/s,推算总位移量在13.5km左右。在花岗岩体以外没有韧性剪切变形现象,说明该韧性剪切带是衡山岩体定位过程中由白石峰岩体沿南岳岩体边缘侵位的简单剪切作用所形成。 相似文献
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为解决雅鲁藏布江缝合带西段南带中数个大型超镁铁岩体的成因问题,对南带西段约400 km2的东波蛇绿岩开展区域地质填图,研究蛇绿岩岩石组合和构造性质及西北缘均质辉长岩年代学和成因.研究表明,东波蛇绿岩以地幔橄榄岩、薄层洋壳和周缘出露大面积晚侏罗世-早白垩世残余海山为特征,地幔橄榄岩中发育大量拆离、韧性剪切和正断层及糜棱岩和糜棱岩化蛇纹岩和蛇绿角砾岩;均质辉长岩的锆石普遍受到流体交代,锆石U-Pb年龄为129.0±1.8 Ma,地球化学具有低Si、K、P、Fe和Ti,高Ca和Mg,N-MORB型的稀土配分特征及明显的Th、Nb、Sr和Pb负异常.认为均质辉长岩形成于慢速-超慢速大洋扩张阶段,在大洋核杂岩沿拆离断层侵位过程中形成. 相似文献
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以前有关深成岩体的侵位研究都试图解释岩体侵位空间如何形成。事实上,幔源岩浆侵位期间在地壳中“制造空间”的途径不外乎;(1)莫霍面降低;(2)地球表面外移。其它的“岩体侵位机制”均是不增加地壳体积的物质迁移作用(MTPs)。得到广泛引用的“同心带状气球膨胀岩体”侵位时的MTPs是岩体附近围岩的韧性流动。这类深成岩体附近可能形成的构造和总应变与岩体的三维形态、接触变质带的宽度以及岩体是否为刺穿底辟有关 相似文献
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B. K. Davis 《Australian Journal of Earth Sciences》2013,60(6):789-797
Country‐rock structures adjacent to plutons of the linear, northwest‐southeast‐trending Mt Alto Supersuite, Hodgkinson Province, northeastern Australia, are variably developed from north to south along the belt. S3 and S4 cleavages show close temporal relationships with pluton emplacement and are better and more widely developed around plutons in the north, whereas much weaker cleavages of the same generation are only sporadically developed to the south. Cleavage trend lines anastomose around less elongate plutons to the north but are generally truncated by more elongate plutons to the south. It is proposed that a major crustal dislocation, the Alto Fault Zone, comprises a set of subparallel structures that formed prior to granite intrusion and controlled emplacement of some plutons and their final shapes. The north‐south variation in structural relations is interpreted to reflect a corresponding variation in depth of emplacement from north to south, which resulted when post‐emplacement reactivation of the Alto Fault Zone uplifted and sinistrally displaced the northern end of the supersuite relative to the southern end. Reactivation of the fault zone after granite emplacement is supported by the truncation of some plutons. 相似文献
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The Bangong-Nujiang suture zone (BNSZ) separates the Lhasa terrane from the Qiangtang terrane and contains remnants of the Bangong-Nujiang oceanic lithosphere (ophiolites). Despite decades of research, when and how the Bangong-Nujiang ophiolites were emplaced remains enigmatic. In the Gerze area (western segment of the BNSZ), the geochemistry and provenance discrimination of chromian spinels (Cr-spinels) from the pre-collisional subduction complex (Mugagangri Group) and syn-collisional peripheral foreland basin succession (Wuga Formation) can help us solve this fundamental problem in the BNSZ evolution. This study compares the geochemistry of Cr-spinels from the Mugagangri Group and Wuga Formation with those from the Bangong-Nujiang ophiolites. Cr-spinels in the Bangong-Nujiang ophiolites have either low TiO2 (0.01–0.15%) and low Al2O3 (11.74–26.76%), indicating an SSZ peridotite origin, or high Al2O3 (45.28–49.15%), indicating a MORB peridotite origin. Cr-spinels from the ultramafic fragments within the Mugagangri Group have extremely low TiO2 (<0.06%) and geochemically overlap with those from the Dong Co ophiolite, suggesting that these ultramafic fragments were sourced from the Dong Co ophiolite above the subduction zone rather than off-scrapped remnants from the subducting oceanic lithosphere. Compositional fingerprints of detrital Cr-spinels from the Wuga Formation indicate provenance either derived from the Bangong-Nujiang ophiolites or recycled from the Mugagangri Group in the north, with minor input possibly from the Lhasa terrane in the south, consistent with the depositional pattern of a peripheral foreland basin. Provenance data reveals that the Bangong-Nujiang ophiolites in the Gerze area had been emplaced and exposed to erosion during northward oceanic subduction prior to the Lhasa-Qiangtang collision. Contrasting the Tethyan-type Yarlung-Zangbo ophiolites in southern Tibet, the Bangong-Nujiang ophiolites in central Tibet are Cordilleran-type in terms of emplacement mechanism, which were uplifted above sea-level by progressive growth of the subduction complex structurally beneath ophiolite. The emplacement of the Cordilleran-type ophiolites in the western segment of the BNSZ is divided into two stages: (1) intra-oceanic subduction initiation at ~177–179 Ma based mainly on zircon U-Pb dating of plagiogranite from the SSZ-type Laguo Co ophiolite; (2) accretionary emplacement of the ophiolites at ~151–168 Ma constrained by the depositional age of the Mugagangri subduction complex. Final closure of the Bangong-Nujiang Tethyan Ocean may convert the ophiolite emplacement mechanism from “accretionary” to “collisional” at ~150–152 Ma, evidenced by the first development of a peripheral foreland basin. 相似文献
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塔里木古大陆东缘的微大陆块体群 总被引:19,自引:0,他引:19
塔里木古大陆东缘至少存在4个微大陆,自北而南分别是阿拉善、祁连、欧龙布鲁克和柴达木微大陆,它们有相近但又有一定差异的早前寒武纪变质基底和中元古代变质沉积地层。每一个微大陆边缘均有复杂的生成历史,特别是新元古代早期的热-构造事件十分发育,并在柴达木微大陆北缘形成一条长700km的花岗片麻岩带,而在多数微大陆边缘则叠加了寒武纪至奥陶纪火山弧或蛇绿混杂岩。在微大陆之间自北而南分别发育了北祁蛇绿岩混杂岩带、南祁连蛇绿岩混杂岩带、沙柳河-鱼卡河高压-超高压变质带和昆仑中部清水泉蛇绿混杂岩,它们代表了微大陆这间的结合带,其形成时代集中在寒武纪至奥陶纪。这几个微大陆总体表现出亲塔里木古大陆的特征,特别是自新元古代以来具有相似的地质演化特征。 相似文献
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The Beja-Acebuches Ophiolitic Complex (BAOC) (south Portugal/Spain) corresponds to a high grade metamorphic belt along the boundary between Ossa-Morena and the South Portuguese Zones and comprises a lithostratigraphic sequence including (from top to bottom) metabasalts, (metamorphosed) multiple dyke intrusions in gabbro, flasergabbros and metaserpentinites. It is affected by three deformation phases. D1 affects the ophiolite lower stratigraphic units and is represented by a mylonitic cleavage with a stretching lineation where shear criteria indicates the sense of shear to be towards the north-north-east; this deformation event can be related to the ophiolite emplacement above the crystalline footwall of the Serpa antiform, affecting Precambrian basement and Cambrian cover rocks. The obduction polarity ist north-eastwards, similar to the subduction polarity that generates the Beja Gabbroic Complex (BGC), implying a flake geometry. The second deformation phase, D2, is represented by an intense WNW-ESE sinistral shear event which is responsible for the shattered appearance of the suture; D2 is reactivated later by a more brittle D3 event involving thrusting to the south-west, again with a sinistral component. 40Ar/39Ar isotopic ages were obtained for (metamorphosed) multiple dyke intrusions in the BAOC's gabbro (342.6 ± 1.4 Ma), for metagabbroic cumulates (340.7 ± 1.9 Ma), and for the undeformed/unmetamorphosed BGC (341.1 ± 1.3 Ma) occurring to the north of the ophiolitic suture. These ages reflect a last regional cooling event in the area which post-dates the ophiolite emplacement and the intrusion of the BGC through this oceanic sequence.
Correspondence to: P. Fonseca 相似文献
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The Aladag region of eastern Taurides, Turkey, is characterized by an imbricated thrust structure developed during late stage emplacement of the Pozanti-Karsanti ophiolite onto the Menderes-Taurus block in the late Cretaceous. The mid to late Cretaceous dynamothermal metamorphic sole and the underlying unmetamorphosed mélange, here named the Aladag accretionary complex, were accreted to the base of the Pozanti-Karsanti ophiolite during intra-oceanic subduction, transport and final obduction of the ophiolite onto the Menderes-Taurus block.In the dynamothermal metamorphic sole, intensity of deformation and degree of metamorphism increase from the base to the top, and at least three episodes of foliation, lineation and fold development are recognized. The asymmetry of quartz c-axis fabrics, tightness and asymmetry of folds of the same generation, and curvature of fold hinge lines increase from base to top, indicating that non-coaxial progressive deformation prevailed during the development of the metamorphic sole. The mélange is divided into three major thrust fault-bounded tectonic slivers, each of which is characterized by distinctive types of matrix and block lithologies, structures and deformation style. Kinematic analyses of the dynamothermal metamorphic sole and the mélange reveal that the tectonic transport direction of the Pozanti-Karsanti ophiolite during its emplacement was from north-northwest to south-southeast, suggesting that the Pozanti-Karsanti ophiolite was derived from a Neo-Tethyan ocean to the north of the Menderes-Taurus block. 相似文献
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Marc Hässig Yann Rolland Marc Sosson Ghazar Galoyan Lilit Sahakyan Gültekin Topuz 《Geodinamica Acta》2013,26(3-4):311-330
In the Lesser Caucasus and NE Anatolia, three domains are distinguished from south to north: (1) Gondwanian-derived continental terranes represented by the South Armenian Block (SAB) and the Tauride–Anatolide Platform (TAP), (2) scattered outcrops of Mesozoic ophiolites, obducted during the Upper Cretaceous times, marking the northern Neotethys suture, and (3) the Eurasian plate, represented by the Eastern Pontides and the Somkheto-Karabagh Arc. At several locations along the northern Neotethyan suture, slivers of preserved unmetamorphozed relics of now-disappeared Northern Neotethys oceanic domain (ophiolite bodies) are obducted over the northern edge of the passive SAB and TAP margins to the south. There is evidence for thrusting of the suture zone ophiolites towards the north; however, we ascribe this to retro-thrusting and accretion onto the active Eurasian margin during the latter stages of obduction. Geodynamic reconstructions of the Lesser Caucasus feature two north dipping subduction zones: (1) one under the Eurasian margin and (2) farther south, an intra-oceanic subduction leading to ophiolite emplacement above the northern margin of SAB. We extend our model for the Lesser Caucasus to NE Anatolia by proposing that the ophiolites of these zones originate from the same oceanic domain, emplaced during a common obduction event. This would correspond to the obduction of non-metamorphic oceanic domain along a lateral distance of more than 500?km and overthrust up to 80?km of passive continental margin. We infer that the missing volcanic arc, formed above the intra-oceanic subduction, was dragged under the obducting ophiolite through scaling by faulting and tectonic erosion. In this scenario part of the blueschists of Stepanavan, the garnet amphibolites of Amasia and the metamorphic arc complex of Erzincan correspond to this missing volcanic arc. Distal outcrops of this exceptional object were preserved from latter collision, concentrated along the suture zones. 相似文献
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雅鲁藏布江蛇绿岩带是国内铬铁矿床出露点最多,且铬铁矿石储量、产量最大的一个蛇绿岩带。根据空间展布规律,该岩带被划分为东段(曲水—墨脱)、中段(昂仁—仁布)和西段(萨嘎至中印边境)3部分。其中,西段自萨嘎以西分为南、北两支亚带。长期以来的研究工作主要集中在东段和中段,西段的研究程度非常薄弱,尤其是北亚带。不同区段研究程度的不平衡十分不利于雅鲁藏布江蛇绿岩带内铬铁矿找矿工作的开展。错不扎蛇绿岩体位于雅鲁藏布江缝合带西段的北亚带,呈北西-南东向带状产出,主要由方辉橄榄岩组成,并普遍发育基性岩脉。野外地质调查在该蛇绿岩体中发现了多个铬铁矿化点,矿化体呈透镜状产于方辉橄榄岩中,出露地表的长度为0.5~1m,厚为0.2~0.5 m,矿石均为致密块状。电子探针分析结果表明,错不扎铬铁矿属于高铬型铬铁矿,铬尖晶石的Cr#[=100×Cr/(Cr+Al)]为75~78,Mg#[=100×Mg/(Mg+Fe2+)]为66~69。计算结果表明,母岩浆的FeO/MgO比值为0.51~0.65,Al2O3和Ti O2含量分别为11.27%~12.1%和0.19%~0.4%,与玻安质岩浆的化学成分相当。然而,针状单斜辉石出溶体的发现指示错不扎铬铁矿可能还经历了一个深部作用过程。 相似文献
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Graciano P. Yumul Jr. Mei-Fu Zhou Christina Yan Wang Tai-Ping Zhao Carla B. Dimalanta 《Journal of Asian Earth Sciences》2008,32(5-6):385
The early Carboniferous Shuanggou ophiolite lies in the middle segment of the Ailao Shan orogenic belt between the South China Block to the north and the Indochina Block to the south. The ophiolite consists of meta-peridotite, gabbro, diabase and basalt, capped by radiolarian-bearing siliceous rocks. No layered gabbros or sheeted dikes have been observed. The meta-peridotite underwent low degrees of partial melting, consistent with the low magma budget of this oceanic lithosphere. Whole-rock rare earth element analyses of gabbro indicate a geochemical affinity with normal mid-ocean ridge basalts, consistent with the crystallization order of plagioclase followed by clinopyroxene recognized in the gabbros. The ophiolite is believed to have formed in a small, slow-spreading oceanic basin. Collision of the Indochina Block with the South China Block in the late Paleozoic was responsible for the closure of the oceanic basin and emplacement of the ophiolite in the Ailao Shan orogenic belt. 相似文献