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1.
通过对内蒙古西部狼山地区进行野外调查,笔者等在狼山南缘的一系列构造逆冲片露头中发现了蛇绿混杂岩。根据野外观测、岩石薄片鉴定、岩石地球化学分析和锆石U-Pb定年等综合研究,确定了蛇绿混杂岩的基质为绿泥石片岩,而混杂岩块包括:紫红色硅质岩、石英角斑岩、玄武岩、蚀变辉绿岩和变质辉长岩等。其中,绿泥石片岩、玄武岩、蚀变辉绿岩中年轻的岩浆锆石年龄将岩浆喷发时代锁定在早白垩世晚期到晚白垩世早期,而且该三种岩石都具有高铝(Al_2O_317%)玄武岩的特征,指示了本区白垩纪与俯冲带相关的构造环境。依据狼山白垩纪蛇绿混杂岩的发现笔者等尝试重新厘定华北克拉通与中亚造山带之间的碰撞时间和边界:作为华北克拉通西北重要组成部分的鄂尔多斯地块在晚白垩世向北俯冲并最终与中亚造山带碰撞拼合,从而造成了阴山造山带西段狼山的隆起。根据构造地貌相似性原理,华北克拉通北部边界可能要从白云鄂博至西拉木伦河一带向南移到阴山—燕山一带,而最后的碰撞时间则由晚古生代推迟到晚白垩世。华北克拉通与西伯利亚克拉通之间的中亚造山带的宽度也进一步向南加宽为整个蒙古南部与内蒙古高原区,构成新的中亚造山带。这一认识为华北克拉通和中亚造山带中新生代构造演化研究以及重要成矿带成因机制探讨提供了新的大地构造模型,也为促进华北克拉通中生代破坏理论的改进提供新的信息和思路。 相似文献
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造山带内蛇绿混杂岩带结构与组成的精细研究可为古板块构造格局重建和古洋盆演化提供最直接证据。北山造山带内存在多条蛇绿混杂岩带,记录了古亚洲洋古生代以来的俯冲和闭合过程,然而其大地构造演化长期存在争议。红石山—百合山蛇绿混杂岩带位于北山造山带北部,主要由蛇绿(混杂)岩和增生杂岩组成,具典型的"块体裹夹于基质"的混杂岩结构特征,发育紧闭褶皱、无根褶皱、透入性面理和双重逆冲构造。蛇绿混杂岩带中岩块主要由超镁铁质-镁铁质岩(变质橄榄岩、辉石橄榄岩、异剥辉石岩、蛇纹岩)、辉长岩、玄武岩、斜长花岗岩、硅质岩等洋壳残块以及奥陶纪火山岩、灰岩等外来岩块组成,基质则主要为蛇纹岩、砂板岩及少量的绿帘绿泥片岩;在蛇绿混杂岩带北侧发育有台地相灰岩与深水浊积岩组成的沉积混杂块体,具滑塌堆积特征。蛇绿混杂岩带内发育三期构造变形,前两期为中深构造层次下形成的透入性变形,第三期为浅表层次的脆性变形,未形成区域性面理。空间上,由增生杂岩和蛇绿(混杂)岩组成的百合山蛇绿混杂岩带共同仰冲于绿条山组浊积岩之上,具有与红石山地区蛇绿混杂岩带相似的岩石组成、构造变形和时空结构特征。百合山蛇绿混杂岩带南侧发育同期的明水岩浆弧,由晚石炭世石英闪长岩-花岗闪长岩-二长花岗岩以及白山组岛弧火山岩组成,其与百合山蛇绿混杂岩带共同构成了北山造山带北部石炭—二叠纪的沟-弧体系,指示了红石山—百合山洋盆向南俯冲的极性。 相似文献
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阿尼玛卿蛇绿混杂岩带位于东昆仑东段南缘,处于秦祁昆缝合系和古特提斯缝合系(Bian,1996)的交接部位。蛇绿岩带呈NWW向延展,长约400km,宽10—50km;由一系列构造岩片构成。在其西段的布青山-牧羊山蛇绿混杂岩带见有晚二叠-三叠纪砂板岩角度不整合在此蛇绿混杂岩之上,不整合面之上有底砾岩。有加里东末期岛弧型花岗-英云闪长岩侵入此蛇绿混杂岩中。前人认为该蛇绿岩的时代属晚二叠-中三叠世(姜春发等,1992;许志琴等,1996;王国灿等,1998)。最近,作者于此蛇绿岩带中发现了早古生代和早石炭-早二叠世蛇绿岩,证明阿尼玛卿蛇绿岩带是一条包含有早古生代、早石炭-早二叠世和晚二叠-中三叠世三个时代蛇绿岩的复合蛇绿混杂岩带。 相似文献
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青海沱沱河地区乌石峰蛇绿混杂岩位于西金乌兰-风火山逆冲带中。通过对其岩石学和全岩地球化学研究,探讨了蛇绿混杂岩的构造类型及其形成环境。晚古生代乌石峰蛇绿构造混杂岩的岩石组合以及蛇绿混杂岩中玄武岩类岩石(主要为辉绿岩及辉长岩)的地球化学特征对构造环境的指示表明:其地球化学特征与MORB相似,超基性岩和基性岩形成于大洋板内环境与洋中脊环境的复合构造环境中。是古特提斯洋洋盆残片,体现了古特提斯洋壳的闭合位置,是古特提斯洋在早二叠世末闭合过程中形成的增生楔的一部分。 相似文献
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《地质通报》2020,(9)
白云山蛇绿混杂岩带位于内蒙古北山造山带中部,呈北西西向展布,向东延伸至月牙山-洗肠井蛇绿混杂岩带,向西延伸至牛圈子-红柳园蛇绿混杂岩带。白云山蛇绿混杂岩带内发育俯冲期的糜棱面理褶皱、拼贴期逆冲断层系及隆升期走滑断层系3期构造变形,由不同类型的岩块与基质组成,岩块主要包括纯橄岩、辉橄岩、橄辉岩、辉石岩、碳酸盐化超基性岩、辉长岩、玄武岩、斜长花岗岩蛇绿岩岩块及硅质岩、灰岩和砂岩岩块,基质主要为蛇纹岩、绿泥片岩及砂板岩。在蛇绿混杂岩带中部发现保存较完整的洋壳残片,由南向北依次出露堆晶超镁铁质岩、堆晶辉长岩及变质玄武岩。结合大洋中脊玄武岩、洋岛玄武岩及晚寒武世岛弧钙碱性辉长岩的识别,认为白云山蛇绿混杂岩带寒武纪发育MOR型、OIB型、SSZ型等不同构造环境的蛇绿岩岩块,俯冲作用持续到晚志留世。 相似文献
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南天山区域大地构造与演化 总被引:27,自引:0,他引:27
塔里木和中天山之间的南天山造山带,经历了复杂的构造演化与地壳增生过程。综合分析南天山造山带的构造、地层、古生物、岩石、地球化学和同位素年代学等方面的资料,特别是放射虫、蛇绿岩、蓝片岩等方面的最新研究成果,讨论了南天山的区域构造格局和演化过程。南天山主体为一上百公里宽的增生-碰撞混杂带-南天山(蛇绿)混杂带;其北侧为中天山岛弧,是仰冲壳楔;南侧为塔里木陆块,是俯冲壳楔。古南天山洋为一广阔的大洋,南天山碰撞造山作用起始于二叠纪末-三叠纪初,新近纪-第四纪进入陆内造山作用阶段。 相似文献
7.
黑龙江东部饶河境内的层状燧石是中生代完达山造山带蛇绿混杂岩的重要组成部分,这些层状燧石的构造意义成为人们关注的热点。对完达山造山带饶河三叠纪大佳河组层状燧石280余块定向手标本开展深入的古地磁研究,结果表明这些层状燧石遭受不同程度的重磁化,重磁化的时间推测为晚侏罗世中期—早白垩世之间。说明对黑龙江东部晚侏罗世—早白垩世存在太平洋板块俯冲的响应。本区重磁化的机制是太平洋板块向西俯冲导致的地体增生、拼贴过程中的造山带流体造成的区域性重磁化现象。 相似文献
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北山造山带花牛山岛弧东段钨矿床成矿时代和成矿动力学过程 总被引:4,自引:3,他引:1
北山造山带位于中亚造山带最南缘,为多期岛弧、蛇绿混杂岩拼贴而成的增生型造山带;晚古生代,北山造山带的构造活动引发强烈的花岗质岩浆活动,伴随有广泛的钨(钼)成矿作用;本文对北山南带花牛山岛弧三个典型含钨花岗岩体:盘陀山、鹰嘴红山及玉山岩体进行详细的锆石U-Pb年代学、全岩地球化学研究。SIMS锆石U-Pb定年结果表明该区成矿花岗岩分为两个侵入期次:(1)晚志留世月牙山-洗肠井蛇绿混杂岩南段出露花岗岩,其中,盘陀山二长花岗岩422.0±1.5Ma;盘陀山钾长花岗岩417.0±1.7Ma;鹰咀红山钾长花岗岩424.0±1.3Ma;(2)晚二叠世柳园蛇绿混杂带北侧玉山花岗岩体,定年结果为280.8±3.0Ma。岩石地球化学研究表明盘陀山-鹰嘴红山花岗岩带为过铝质S型花岗岩,玉山岩体为A型花岗岩。岩体稀土含量较高,具右倾型稀土配分模式,LREE分异强烈,HREE分异不明显,样品Eu亏损强烈。原始地幔标准化蛛网图中总体显示较为一致的分布模式,大离子亲石元素Ba、Sr呈现明显负异常,富集Th、U、Pb、Zr、Hf等元素而亏损高场强元素Ta、Nb、Ti、P。结合晚古生代北山构造演化过程,推断国庆-鹰嘴红山钨矿为公婆泉岛弧与花牛山岛弧碰撞阶段形成,而玉山钨矿床为晚华力西期弧后伸展构造背景的产物。 相似文献
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10.
塔里木北缘南天山蛇绿混杂岩带沿乌瓦门、库勒湖、依奇科里克、黑英山等地分布,黑英山段蛇绿混杂岩以梅什布拉克牧场一带出露最好。该蛇绿岩时代的确定事关天山造山带形成与演化历史的认识。对采自梅什布拉克蛇绿混杂岩带基质中的20多件硅质岩进行了薄片观察,从中挑选出若干件代表性硅质岩和硅质泥岩做微古化石鉴定,从中发现较多放射虫化石,属于内射虫类和原笼虫类,时代为晚泥盆世法门期—早石炭世杜内期—维宪期,早石炭世代表南天山洋盆关闭的年龄下限,或构造混杂的早期年龄。结合区域地质及其前人研究成果,认为南天山的乌瓦门、库勒湖、依奇科里克、黑英山各段蛇绿岩在物质组成与时空延伸上均有可比性,共同构成一个大型的南天山晚古生代构造缝合带。现有资料不支持南天山存在晚二叠世洋盆的认识。 相似文献
11.
在进行1:25万墨脱幅地质调查中,笔者首次在波密地区发现和填绘出了帕隆藏布残留蛇绿混杂岩带。帕窿藏布残留蛇绿混杂岩呈串珠状产出于花岗岩类侵入岩中,其岩石组合为橄揽辉石岩、辉石岩、辉长岩、辉长辉绿岩、辉绿岩、石英岩和大理岩,局部可见条带状硅质岩。上述组分之间的相互关系表明,蛇绿岩在花岗岩类岩石侵入之前发生过构造混杂和变形。根据沉积岩所记录的盆地演化过程、蛇绿岩的Rb-Sr年龄值以及残留蛇绿混杂岩带两刨花岗岩类岩石的特征和生成时代综合分析认为:帕隆藏布残留蛇绿混杂岩带形成于石炭-二叠纪的弧间盆地中,至少在晚三叠纪之前出现洋壳,在消减过程中向北俯冲并在中侏罗世之前闭合(弧-弧碰撞)。 相似文献
12.
中国阿尔泰造山带南缘额尔齐斯断裂带的构造变形及意义 总被引:6,自引:4,他引:2
额尔齐斯断裂是中亚造山带中的一条重要深大断裂,对于额尔齐斯断裂运动性质一直有着走滑断层、逆冲断层和压扭性断层等不同看法.本文在中国阿尔泰造山带南缘开展了详细的构造地质学工作,研究结果表明,额尔齐斯断裂及其次级断裂组成额尔齐斯断裂带.额尔齐斯断裂带在中国境内是一条宽约20 ~ 40km,长约400km,经受不同程度构造作用的强应变带,剪切作用影响范围遍布整个中国阿尔泰造山带南缘.额尔齐斯断裂带经历了左行走滑和右行走滑两个阶段.结合前人有关韧性剪切带成因型金矿、同构造岩体侵位与变形关系及对变质岩石40Ar/39Ar年代学研究,本文认为额尔齐斯断裂带的左行走滑构造形成于早二叠世(283~275Ma).早二叠世之后,额尔齐斯断裂带叠加了右行走滑事件,其活动时限可能为晚二叠世(260 ~ 245 Ma),其规模远远小于前期的左行走滑构造.额尔齐斯断裂带走滑活动性质的确定,为二叠纪北疆及整个中亚造山带造山后调整过程中不同的构造方式提供了佐证. 相似文献
13.
How many sutures in the southern Central Asian Orogenic Belt:Insights from East Xinjiang-West Gansu(NW China)? 总被引:1,自引:0,他引:1
Wenjiao Xiao ;Chunming Han ;Wei Liul ;Bo Wan ;Ji'en Zhang ;Song jian Ao ;Zhiyong Zhang ;Dongfang Song ;Zhonghua Tian ;Jun Luo 《地学前缘(英文版)》2014,5(4):525-536
How ophiolitic mèlanges can be defined as sutures is controversial with regard to accretionary orogenesis and continental growth.The Chinese Altay,East junggar,Tianshan,and Beishan belts of the southern Central Asian Orogenic Belt(CAOB) in Northwest China,offer a special natural laboratory to resolve this puzzle.In the Chinese Altay,the Erqis unit consists of ophiolitic melanges and coherent assemblages,forming a Paleozoic accretionary complex.At least two ophiolitic melanges(Armantai,and Kelameili) in East Junggar,characterized by imbricated ophiolitic melanges,Nb-enriched basalts,adakitic rocks and volcanic rocks,belong to a Devonian-Carboniferous intra-oceanic island arc with some Paleozoic ophiolites,superimposed by Permian arc volcanism.In the Tianshan,ophiolitic melanges like Kanggurtag,North Tianshan,and South Tianshan occur as part of some Paleozoic accretionary complexes related to amalgamation of arc terranes.In the Beishan there are also several ophiolitic melanges,including the Hongshishan,Xingxingxia-Shibangjing,Hongliuhe-Xichangjing,and Liuyuan ophiolitic units.Most ophiolitic melanges in the study area are characterized by ultramafic,mafic and other components,which are juxtaposed,or even emplaced as lenses and knockers in a matrix of some coherent units.The tectonic settings of various components are different,and some adjacent units in the same melange show contrasting different tectonic settings.The formation ages of these various components are in a wide spectrum,varying from Neoproterozoic to Permian.Therefore we cannot assume that these ophiolitic melanges always form in linear sutures as a result of the closure of specific oceans.Often the ophiolitic components formed either as the substrate of intra-oceanic arcs,or were accreted as lenses or knockers in subduction-accretion complexes.Using published age and paleogeographic constraints,we propose the presence of (1) a major early Paleozoic tectonic boundary that separates the Chinese Altay-East Junggar multiple subduction system 相似文献
14.
班公湖—双湖—怒江—昌宁—孟连对接带时空结构——特提斯大洋地质及演化问题 总被引:1,自引:1,他引:0
班公湖—双湖—怒江(中北段)—昌宁—孟连对接带广泛出露特提斯大洋岩石圈俯冲消减过程中产生的不同时代、不同构造环境、不同变质程度、不同变形样式的洋板块构造地层系统、增生混杂的构造—岩石组合体,可识别出增生的远洋沉积岩、海沟浊积岩、古生代—中生代蛇绿岩、蛇绿混杂岩、洋岛-海山消减增生楔、洋底沉积增生杂岩,基底残块以及以蓝片岩、榴辉岩为代表的高压—超高压变质岩带,记录了青藏高原原古特提斯大洋形成演化的地质信息。班公湖—双湖—怒江—昌宁—孟连对接带是青藏高原中部一条重要的原古特提斯大洋自北向南后退式俯冲消亡的巨型增生杂岩带,构筑了冈瓦纳大陆与劳亚-泛华夏大陆分界带。 相似文献
15.
The main site and timing of the final closure of the middle segment of the Paleo-Asian Ocean (PAO) has been an issue of hot debate, which hampers us from better understanding the late-stage tectonic evolution of the Central Asian Orogenic Belt (CAOB). Synthesizing the available geological records for the ophiolitic mélanges in the Beishan Orogenic Belt (BOB), we regard the Liuyuan ophiolitic mélange as the main site of the final closure of the middle segment of the PAO. To determine the final closure time of the middle segment of the PAO, this study mainly applied field-based, systematic zircon U-Pb-Hf isotopic analyses for the Carboniferous and Permian sedimentary successions on the northern and southern sides of the Liuyuan ophiolitic mélange. Our results indicate that the late Carboniferous sedimentary successions north of the Liuyuan mélange consisting mainly of interbedded sandstone and siltstone with minor conglomerate show primarily affinity with a local, single source, i.e. the constituent units of the BOB north of the Liuyuan mélange. They were closely associated with the northward subduction of the middle segment of the PAO. By contrast, the unconformably overlying Permian clastic deposition on both sides of the Liuyuan ophiolitic mélange shows comparable lithology that fines from a thick sequence of conglomerate at the base to thin-bedded turbidite sequences up section. These Permian units were probably deposited in a progressively deepening basin within an extensional post-collision regime after the disappearance of the middle segment of the PAO. All the <274–261 Ma sandstones on both sides of the Liuyuan ophiolitic mélange were derived from commingling source regions on both sides of the Liuyuan mélange, as supported by comparable, diagnostic ages and εHf(t) values between the studied detrital zircons and coeval magmatic zircons from the BOB and north Tarim. Such a marked transition from a single, local provenance in the late Carboniferous to commingling provenances at ca. 274–261 Ma indicates the final closure of the middle segment of the PAO prior to the end of the early Permian. In conjunction with available data for the eastern and western segments of the PAO, we establish the eastward-younging, scissor-like closure for the whole PAO during mid Carboniferous to Early Triassic time. 相似文献
16.
西准噶尔南部玛依勒洋盆开启、闭合时限:来自中泥盆统与下伏地质体之间角度不整合关系的证据 总被引:5,自引:2,他引:3
新疆西准噶尔南部地区出露多条蛇绿岩,其中玛依勒蛇绿岩是该地区比较重要的蛇绿岩之一,其所代表的古洋盆的开启、闭合时限一直是地学界争论的焦点。详细的野外调查发现:玛依勒蛇绿混杂岩呈构造岩块的形式就位于中-上志留统玛依拉山岩群复理石基质中或与寒武纪杂岩体在空间上密切共生,表明玛依勒蛇绿岩所代表的古洋盆至少在寒武纪时期就已经开启,一直持续到中-晚志留世;中泥盆统库鲁木迪组分别角度不整合于中-上志留统玛依拉山岩群和寒武纪杂岩体之上,从而限定了玛依勒洋盆闭合时限的上限为中泥盆世之前。地层剖面分析发现库鲁木迪组与玛依拉山岩群之间在岩性特征、地层序列、沉积环境等方面均存在显著差异,表明晚古生代早期是西准噶尔地区构造演化发展的重要转换时期,库鲁木迪组下部的陆相沉积序列是对玛依勒早古生代洋盆闭合过程的沉积学响应。这将对进一步研究西准噶尔的构造演化和古生代中亚地区的构造格局提供了重要的制约。 相似文献
17.
西准噶尔晚古生代岩浆活动和构造背景 总被引:18,自引:7,他引:11
西准噶尔作为中亚造山带的一部分,吸引了大量学者的关注。蛇绿混杂岩带、花岗岩、中基性岩墙在本地区广泛出现,表明西准噶尔晚古生代构造演化极为复杂。但是在许多方面仍存在很多争议,例如西准噶尔蛇绿混杂岩带的形成时代、岩石组合和岩石成因;I型和A型花岗岩的岩石成因,构造背景和热机制;中基性-酸性岩墙群的年代学、岩石成因、构造背景和古应力场;西准噶尔晚古生代年代学格架和构造背景;西准噶尔显生宙地壳增生;西准噶尔基底特征和西准噶尔晚古生代构造演化等。笔者通过搜集前人的资料和数据,对西准噶尔区域发育的蛇绿混杂岩带、地层、古地理环境、花岗岩体和中基性岩墙群的总结,结合项目组野外与室内数据的研究,得到以下认识:(1)达尔布特和克拉玛依蛇绿混杂岩的形成环境为与俯冲相关的弧后盆地,源区来自含尖晶石二辉橄榄岩高程度部分熔融作用;(2)早石炭世花岗岩形成于俯冲环境,晚石炭世-早二叠世花岗岩形成于后碰撞环境,中二叠世花岗岩形成于板内环境;(3)I型花岗岩的成因与俯冲密切相关,而A型花岗岩和中基性岩墙产于后碰撞环境下;(4)A型花岗岩是下地壳受地幔底侵发生部分熔融并高度分离结晶的产物,中基性岩墙群普遍具有埃达克质岩的地球化学特点,可能产于受流体(或熔体)交代的残余洋壳板片的部分熔融;(5)中基性岩墙群稍晚于寄主岩体而形成,但两者均形成于后碰撞构造背景。在晚石炭世-早二叠世,西准噶尔处于近南北向的拉张应力体系;(6)西准噶尔在泥盆纪为洋盆体系;早石炭世,俯冲-碰撞过程结束;晚石炭世-早二叠世属于后碰撞环境;中晚二叠世处于板内环境。 相似文献
18.
In this paper we discuss the timing of final closure of the Paleo-Asian Ocean based on the field investigations of the Carboniferous–Permian stratigraphic sequences and sedimentary environments in southeastern Inner Mongolia combined with the geology of its neighboring areas. Studies show that during the Carboniferous–Permian in the eastern segment of the Tianshan-Hinggan Orogenic System, there was a giant ENE–NE-trending littoral-neritic to continental sedimentary basin, starting in the west from Ejinqi eastwards through southeastern Inner Mongolia into Jilin and Heilongjiang. The distribution of the Lower Carboniferous in the vast area is sparse. The Late Carboniferous or Permian volcanic-sedimentary rocks always unconformably overlie the Devonian or older units. The Upper Carboniferous–Middle Permian is dominated by littoral-neritic deposits and the Upper Permian, by continental deposits. The Late Carboniferous–Permian has no trace of subduction-collision orogeny, implying the basin gradually disappeared by shrinking and shallowing. In addition, it is of interest to note that the Ondor Sum and Hegenshan ophiolitic mélanges were formed in the pre-Late Silurian and pre-Late Devonian respectively, and the Solonker ophiolitic mélange formed in the pre-Late Carboniferous. All the evidence indicates that the eastern segment of the Paleo-Asian Ocean had closed before the Late Carboniferous, and most likely before the latest Devonian (Famennian). 相似文献
19.
《International Geology Review》2012,54(5):633-656
The West Junggar lies in the southwest part of the Central Asian Orogenic Belt (CAOB) and consists of Palaeozoic ophiolitic mélanges, island arcs, and accretionary complexes. The Barleik ophiolitic mélange comprises several serpentinite-matrix strips along a NE-striking fault at Barleik Mountain in the southern West Junggar. Several small late Cambrian (509–503 Ma) diorite-trondhjemite plutons cross-cut the ophiolitic mélange. These igneous bodies are deformed and display island arc calc-alkaline affinities. Both the mélange and island arc plutons are uncomfortably covered by Devonian shallow-marine and terrestrial volcano-sedimentary rocks and Carboniferous volcano-sedimentary rocks. Detrital zircons (n = 104) from the Devonian sandstone yield a single age population of 452–517 million years, with a peak age of 474 million years. The Devonian–Carboniferous strata are invaded by an early Carboniferous (327 Ma) granodiorite, late Carboniferous (315–311 Ma) granodiorites, and an early Permian (277 Ma) K-feldspar granite. The early Carboniferous pluton is coeval with subduction-related volcano-sedimentary strata in the central West Junggar, whereas the late Carboniferous–early Permian intrusives are contemporary with widespread post-collisional magmatism in the West Junggar and adjacent regions. They are typically undeformed or only slightly deformed. Our data reveal that island arc calc-alkaline magmatism occurred at least from middle Cambrian to Late Ordovician time as constrained by igneous and detrital zircon ages. After accretion to another tectonic unit to the south, the ophiolitic mélange and island arc were exposed, eroded, and uncomfortably overlain by the Devonian shallow-marine and terrestrial volcano-sedimentary strata. The early Carboniferous arc-related magmatism might reflect subduction of the Junggar Ocean in the central Junggar. Before the late Carboniferous, the oceanic basins apparently closed in this area. These different tectonic units were stitched together by widespread post-collisional plutons in the West Junggar during the late Carboniferous–Permian. Our data from the southern West Junggar and those from the central and northern West Junggar and surroundings consistently indicate that the southwest part of the CAOB was finally amalgamated before the Permian. 相似文献
20.
Mélanges occur as discontinuous, mappable, units along an extensive N–S-trending, steeply dipping zone of distributed shear in metamorphic complexes along the coast of central Chile. Large mélange zones, from north to south, near Chañaral, Los Vilos, Pichilemu, and Chiloé Island, contain variations in lithologic and structural detail, but are consistent in exhibiting cross-cutting fabric features indicating a progressive transition from earlier ductile to more brittle deformation. In the Infiernillo mélange near Pichilemu, Permian to Early Triassic, sub-horizontal schistosity planes of the Western Series schist are disrupted, incorporated into, and uplifted along high-angle, N–S- to NNE–SSW-trending brittle–ductile shears. Mylonitic and cataclastic zones within the mélange matrix indicate active lateral shear during cumulative exhumation from depths exceeding 12 km in some areas. Exotic lithologies, such as Carboniferous mafic amphibolite and blueschist, formed during earlier Gondwanide subduction, match well with similar rocks in the Bahia Mansa to Los Pabilos region 750 km to the south, suggesting possible dextral offset. The development of the Middle to Late Triassic, N–S=trending, near-vertical shear zones formed weaknesses in the crust facilitating later fault localization, gravitational collapse, and subduction erosion along the continental margin. The length and linearity of this zone of lateral movement, coincident with a general hiatus of regional arc magmatism during the Middle to Late Triassic, is consistent with large-scale dextral transpression, or possible transform movement, during highly oblique NNE–SSW convergence along the pre-Andean (Gondwana) margin. The resultant margin parallel N–S-trending shear planes may be exploited by seismically active faults along the present coastal area of Chile. The palaeo-tectonic setting during the transitional period between earlier Gondwanide (Devonian to Permian) and later Andean (Late Jurassic to present) subduction may have had some similarity to the presently active San Andreas transform system of California. 相似文献