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1.
华北中北部晚太古代高压麻粒岩的地质产状及其出露的区域构造背景 总被引:24,自引:8,他引:16
晋北-冀西北高级变质的灰色片麻岩-花岗质片麻岩杂岩基底内广泛发育晚太古代高压麻粒岩构造透镜体或岩片,几个典型地段的构造填图研究表明,高压麻粒岩主要出露于龙泉关-桑干构造带的东北段,即冀北陆缘活动带与恒山-五台绿岩带之间的高级变质基底内。高压麻粒岩形成与出露的过程中,主要经历4期构造变形:D1低角度逆掩剪切变形;D2NW向伸展作用;D3区域规模的NNE-NE向褶皱;D4大规模右旋走滑剪切变形。以上变形明显受区域构造所控制,先后涉及鄂尔多斯和阜平陆块晚太古代构造拼合,太古代末五台裂谷的张开及闭合,以及早元古代冀北陆缘活动带向南俯冲造成的掀斜作用。 相似文献
2.
北苏鲁荣成地区超高压变质带的形成与折返动力学 总被引:1,自引:0,他引:1
山东省荣成地区位于苏鲁高压-超高压变质带的东北部,以花岗质片麻岩、副片麻岩为主,夹有少量的榴辉岩、石榴辉石岩、麻粒岩、超基性岩、石英岩、大理岩和斜长角闪岩等,各类岩石的锆石中普遍含有柯石英包裹体,表明荣成地区岩石曾经历超高压变质作用过程。荣成地区区域构造格架表现为面理产状总体为NNE-SSW走向,向南转为由NE-SW走向,呈弧形展布,倾向SE或SSE,超高压变质岩石由一系列近平行的剪切岩片组成,岩片之间的分界线为一些韧性剪切带,是折返阶段角闪岩相-绿片岩相的产物。结合野外宏观变形现象、显微构造分析以及糜棱岩中石英的优选方位EBSD (electron backscatter diffraction,电子背散射技术)测量结果,可以判断北苏鲁荣成地区韧性剪切带主要形成于中、低温(550~350℃)条件,并具有由NW向SE“斜向正滑”的剪切指向。根据韧性剪切带中所含的榴辉岩透镜体的显微构造和绿辉石与金红石的优选方位的EBSD的研究,重塑超高压变质阶段的流变学特征:绿辉石和金红石都具有高温的滑移系组构模式。横穿苏鲁高压-超高压变质带的地震反射剖面揭示了苏鲁高压-超高压变质带呈厚10km以上的穹形板片,位于苏鲁高压-超高压变质板片下部的荣成及江苏刘山以韧性正断裂系列为主。Ar-Ar测年结果表明,发生这种伸展韧性剪切作用的时间在117~130Ma。位于板片上部的南苏鲁以韧性逆冲性断裂系列为主。基于以上各方面的研究,进一步验证了苏鲁超高压-超高压变质带折返动力学的挤出模式。 相似文献
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大青山高级变质岩不仅记录华北克拉通早期大陆形成演化历史,也保留了中下部地壳岩石流变信息,它们经历了下部地壳构造层次高角闪岩相-麻粒岩相条件变质变形、深熔作用改造,形成了复杂构造样式和构造要素组合.韧性剪切带是高级变质岩中主要构造形迹,控制着早前寒武纪高级变质岩主体构造格架.依据野外地质产状、变形特征与构造要素叠加改造关系,韧性剪切带划分为早期近水平顺层伸展型和晚期陡倾韧性剪切带.近水平顺层伸展韧性剪切带呈残留状保留在后期变形改造较弱部位上,主要沿着不同地质单元或者岩性层界面上发育,是在伸展变形体制下形成的.晚期陡倾韧性剪切带呈近东西方向展布,规模较大,叠加和改造早期构造形迹,形成于晚期造山挤压构造环境中,以左行滑移为主.这两种韧性剪切带都形成于地壳中深部构造层次高角闪岩相-麻粒岩相条件下,变形机制主要为熔体增强颗粒边界扩散和颗粒流动,使岩石发生大规模的塑性流动.在宏观上形成了不对称流动组构、条纹条带构造、熔融线理、层内流动褶皱等构造形迹,在微观上矿物晶体没有发生明显塑性变形,均匀消光,晶体为三边平衡结构,与静态变质结构相似,形成了地壳深部构造层次上变质构造岩-构造片麻岩. 相似文献
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桂东南那卜地区潭超单元及其围岩中,主期变形变质作用形成的韧性剪切带可分为2类:NE向右行走滑性质的韧性剪切带;NW向逆冲推覆性质的韧性剪切带。通过对以上2类韧性剪切带的构造样式、显微组构以有运动学特征等的综合分析表明,它们形成的构造应力是NE-SW向的,在这一应力的作用下,使早期NE向和NW向构造重新活动,从而构成了一种NE向走滑-NW向逆冲的相互转换程式,即NE向右行走滑性质韧性剪切带和NW向逆冲推覆性质韧性剪切带相互转换的韧性变形体系。 相似文献
5.
山西龙泉关韧性剪切带新认识 总被引:2,自引:0,他引:2
龙泉关韧性剪切带位于山西、河北两省分水岭两侧的狭长地区内,全长约100km,宽2~14km,总体呈北北东向带状展布。据其变形特征在横、纵向上的明显变化,可分北、中、南三段:北段由眼球状片麻岩、长英质糜棱岩及构造透镜体组成,片麻岩中发育各类旋转碎斑构造,指示上盘(西盘)左旋剪切;中段由强直片麻岩组成,发育平直的片麻理及矿物拉伸线理,为S—L构造岩;南段由一系列线状强变形带及所挟持包绕的弱应变域所组成,变形岩石发育条带状、杆状构造。该剪切带内含有不同时期的变质岩系,主体为中太古代阜平期变质岩系,其构造形迹为一多期多相叠加的韧性剪切带;五台早期表现为伸展型近水平韧性剪切变形,是五台海盆早期扩张或裂解阶段的直观反映;吕梁期韧性剪切变形表现为逆冲推覆型。其形成及构造演化是区内早前寒武纪地质演化的缩影。 相似文献
6.
喜马拉雅东构造结——南迦巴瓦构造及组构运动学 总被引:30,自引:13,他引:17
喜马拉雅东端-南迦巴瓦构造结的构造格架总体呈现由叠置构造岩片构成的复式背形构造.自NW到SE由比鲁构造岩片、直白构造岩片、南派乡构造岩片和多雄拉变质穹隆组成,它们之间的界限分别是直白-丹娘-南伊沟韧性拆离断裂、直白-丹娘韧性逆冲断裂和多雄拉韧性逆冲断裂.由高压麻粒岩相组成的直白构造岩片被直白-丹娘-南伊沟韧性拆离断裂和直白-丹娘韧性逆冲断裂所夹持,为挤出构造岩片.根据印度斯-雅鲁藏布江大拐弯缝合带西侧和北侧的变形特征及石英组构运动学的EBSD测量结果,表明大拐弯缝合带存在各段的差异,并具有逐渐演化的特征.大拐弯缝合带的北端为拉月-迫隆乡韧性逆冲剪切带;西段为鲁朗-拉月左行走滑剪切带,西南段为嘎马-米林左行伸展转换剪切带,指示南迦巴瓦变质体相对拉萨地体的运动转为水平走滑运动.根据大拐弯缝合带东侧右行走滑和西侧左行走滑特征,推测在印度-亚洲碰撞之后,南迦巴瓦变质体受制于这两条走滑断裂,而相对喜马拉雅地体向北推移,并深深插入拉萨地体之下,形成东构造结.由于南迦巴瓦变质体的强烈上隆,其上部原存的特提斯喜马拉雅的古生代-中生代盖层沉积被俯冲和被剥蚀贻尽.南迦巴瓦变质体中直白组高压麻粒岩相中石榴石辉石岩形成的温压条件(T=800~900℃,P=2.6~2.8GPa)表明,岩石经历了相当于80km~100km深度的峰期榴辉岩变质作用的条件,印度板片深俯冲于拉萨地体之下又折返挤出到由派乡组和多雄拉组角闪岩相(混合岩化)组成的南迦巴瓦变质基底之中. 相似文献
7.
CCSD主孔100-2950m榴辉岩类和片麻岩类叶理及微断层产状特征 总被引:1,自引:0,他引:1
CCSD主孔100~2950m榴辉岩、退变榴辉岩类岩石叶理倾角明显较片麻岩类岩石叶理倾角陡,前者总体倾角55°左右,后者28°左右,局部可见片麻岩类叶理切割榴辉岩类叶理,因此两者叶理可能形成于不同时期;两类岩石之间现部分为韧性剪切带接触关系,韧性剪切带形成于苏鲁地体折返主期自SEE向NWW的韧性剪切作用。榴辉岩、退变榴辉岩类岩石叶理产状对发育于该类岩石内的微断层产状有一定控制作用,而片麻岩类岩石叶理产状对发育于该类岩石内的微断层产状控制作用相对较弱。孔区脆性变形主要反映白垩纪以来SEE-NWW向伸展构造应力场的变形特征,主孔100~1620m倾伏向以SEE向占绝对优势的微正滑断层擦痕即为该期变形的产物。 相似文献
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医巫闾山变质核杂岩南段韧性变形与流变特征 总被引:1,自引:1,他引:0
医巫闾山变质核杂岩南段张家堡地区出露两套花岗质岩石:太古代花岗质片麻岩,含有黑云斜长片麻岩包体,以及晚期侵位钾长花岗片麻岩与花岗岩脉。详细宏微观构造分析发现,花岗质岩石遭受了两期变形事件:晚侏罗世高温韧性剪切和早白垩世低温韧性剪切变形。早期韧性变形温度约550~600℃,高绿片岩相-低角闪岩相,此次韧性变形以单剪作用为主,岩石为L=S和LS构造岩,具有右行剪切特征。晚期韧性变形温度约400~450℃,绿片岩相,变形以纯剪切为主的一般剪切,岩石以L=S构造岩为主,具有左行剪切特征。利用动态重结晶及亚颗粒粒径估算岩石流变学参数,结果表明高温剪切带具有较低差异应力,较高应变速率,低温剪切带恰好相反。早期晚侏罗世韧性伸展变形与伊泽那崎板块和法拉隆板块NNW向俯冲共同作用于欧亚大陆东缘相关,进入早白垩世伊泽纳崎板块向欧亚大陆俯冲深部板块后撤(Roll-back),导致华北岩石圈发生大规模减薄,医巫闾山地区发生晚期低温韧性伸展变形。 相似文献
9.
喜马拉雅造山带中段麻粒岩绝大多数呈透镜状、布丁体等弱应变域断续产出,强应变带围岩往往发育糜棱面理和构造片理。部分麻粒岩经历了强烈的韧性剪切构造变形,形成剪切透镜体,并且明显受韧性剪切带控制,显示成带分布、局部集中的特点。根据矿物组合可将产出的麻粒岩分为4种麻粒岩,其主要组成矿物如斜方辉石、单斜辉石、斜长石、角闪石以及石榴石等均不同程度地发生扭折、压扁、拉长扭曲、亚颗粒化及边缘强烈动态重结晶等强烈塑性显微构造变形特征。研究分析表明,麻粒岩的产出与重熔花岗岩的侵位及藏南伸展拆离断层活动有关,在喜马拉雅造山带强烈伸展快速抬升造山的绝热降压大陆动力学过程中,下地壳基性麻粒岩以较快的速率上升到地表,而下地壳层流作用、造山带伸展-隆升-造山导致麻粒岩相变质作用。 相似文献
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11.
大量含石榴石的基性麻粒岩透镜体出露于苏鲁变质带的北部及邻近地区,它们可能是再变质的高压变质岩石。在详细的岩相学研究的基础上,确定采自莱西和文登的样品WD01、WD04、ML06 是由高压麻粒岩经中-高压麻粒岩相再变质形成的,而采自威海的样品WH1 是由柯石英榴辉岩经中-高压麻粒岩相再变质形成的。Sm-Nd 同位素年代学研究也证实了二者的重大差别。3 个高压麻粒岩样品的矿物-全岩内部等时线年龄分别是1 846+ /-76Ma,1 743+ /-79Ma 和1 752+ /-30Ma,TDM 模式年龄是3.3Ga,3.0Ga 和2.8Ga.上述数据说明原岩形成在太古宙,而1 800Ma 是麻粒岩相降压变质事件的记录,这与华北克拉通前寒武纪高压麻粒岩的年代学一致。威海样品的Sm-Nd 同位素特征则完全不同。矿物和全岩形不成等时线,表现出它们之间的同位素不平衡。εNd(0)值高达+ 127,TDM 模式年龄是1.3Ga.这与Jahn(1994,1996)对威海同类样品的测定结果相同。可以推测威海样品的原岩是元古宙岩石,在后来复杂的变质过程中,在水岩相互作用和岩浆及重熔作用的影响下,同位素系统发生重大变化。同位素年代学为苏鲁变质带和华北克拉通的界限是昆嵛山岩浆-变质杂岩带提供了依据。 相似文献
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大量含石榴石的基性麻粒岩透镜体出露于苏鲁变质带的北部及邻近地区,它们可能是再变质的高压变质岩石。在详细的岩相学研究的基础上,确定采自莱西和文登的样品WD01、WD04、ML06 是由高压麻粒岩经中-高压麻粒岩相再变质形成的,而采自威海的样品WH1 是由柯石英榴辉岩经中-高压麻粒岩相再变质形成的。Sm-Nd 同位素年代学研究也证实了二者的重大差别。3 个高压麻粒岩样品的矿物-全岩内部等时线年龄分别是1 846+ /-76Ma,1 743+ /-79Ma 和1 752+ /-30Ma,TDM 模式年龄是3.3Ga,3.0Ga 和2.8Ga.上述数据说明原岩形成在太古宙,而1 800Ma 是麻粒岩相降压变质事件的记录,这与华北克拉通前寒武纪高压麻粒岩的年代学一致。威海样品的Sm-Nd 同位素特征则完全不同。矿物和全岩形不成等时线,表现出它们之间的同位素不平衡。εNd(0)值高达+ 127,TDM 模式年龄是1.3Ga.这与Jahn(1994,1996)对威海同类样品的测定结果相同。可以推测威海样品的原岩是元古宙岩石,在后来复杂的变质过程中,在水岩相互作用和岩浆及重熔作用的影响下,同位素系统发生重大变化。同位素年代学为苏鲁变质带和华北克拉通的界限是昆嵛山岩浆-变质杂岩带提供了依据。 相似文献
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Abundant garnet-bearing granulite lenses are widely distributed in the northern part of the Sulu region and adjacent areas. They are possibly re-metamorphosed high-pressure metamorphic rocks. On the basis of detailed petrographic study, samples WD01, WD04 and ML06 from Laixi and Wendeng were identified as high-pressure granulites, and WH1 from Weihai as an original coesite-bearing eclogite. Three high-pressure granulite samples give mineral-WR isochron ages of 1846±76, 1743±79 and 1752±30 Ma. TDM ages are 3.3, 3.0 and 2.8 Ga. The Sm–Nd mineral-WR isochron ages are interpreted to date as the metamorphic resetting within the medium-pressure granulite facies, representing an isotopic re-homogeneity during uplifting of the high-pressure granulites from deep continent crust. It is important that Sm–Nd chronological characteristics are the same as Archaean high-pressure granulites in the North China craton. However, sample WH1 from Weihai demonstrates abnormal Sm–Nd characteristics. Its whole rock Nd (0) value is +129. TDM age is 1.3 Ga, and constrains the minimum age of re-metamorphosed eclogite protolith formation to the mid-Proterozoic. This result is identical to those reported by Jahn (1994), showing complicated processes of metamorphism and metasomatism. The data in this paper provide further evidence to define the boundary between the North China craton and UHPM belt in eastern Shandong and to understand the geotectonic nature of the boundary. 相似文献
14.
High-pressure mafic granulites in the Trans-North China Orogen: Tectonic significance and age 总被引:8,自引:2,他引:6
Jian Zhang Guochun Zhao Min Sun Simon A. Wilde Sanzhong Li Shuwen Liu 《Gondwana Research》2006,9(3):349-362
High-pressure mafic granulites (including retrograded eclogites) have been reported from the Trans-North China Orogen, a Paleoproterozoic orogenic belt along which two discrete continental blocks, referred to as the Eastern and Western Blocks, were amalgamated to form the North China Craton. Extensive metamorphic investigations and geochronology carried out over the last few years provide important insights into the age and significance of these high-pressure granulites, which are critical in understanding of the timing and tectonic processes involved in the assembly of the North China Craton.Most high-pressure mafic granulites in the Trans-North China Orogen preserve the high-pressure granulite facies assemblage garnet + plagioclase + clinopyroxene + quartz, the medium-pressure granulite facies assemblage garnet + plagioclase + clinopyroxene + orthopyroxene ± quartz, the low-pressure granulite facies assemblage orthopyroxene + clinopyroxene + plagioclase ± quartz, and the amphibolite facies assemblage hornblende + plagioclase. Minor high-pressure granulites preserve the early eclogite facies mineral assemblage of garnet + quartz + omphacite pseudomorph (clinopyroxene + Na-rich plagioclase), indicating that they are retrograded eclogites. These mineral assemblages and their P–T estimates define a clockwise P–T path involving near-isothermal decompression and cooling following the peak high-pressure metamorphism, which suggests that they formed during continent–continent collision. Field mapping and geochronology indicate that the precursors of these high-pressure granulites were mafic dykes which were emplaced at 1915 Ma and underwent high-pressure granulite facies metamorphism at 1.85 Ga. Taken together, the high-pressure granulites in the Trans-North China are considered to have resulted from final collision between the Eastern and Western Blocks to form the North China Craton at 1.85 Ga, not at 2.5 Ga as recently proposed by some authors. 相似文献
15.
Johildo Salomo Figueirêdo Barbosa Fernando Alves daSilva Najara Santos Sapucaia Sundaram S. Iyer 《Gondwana Research》1998,1(3-4):343-356
New petrological and geochemical characteristics of the Brejtes region, situated in the south of Bahia, Brazil are discussed. The region forms a part of the most important and extensive granulite facies terrain in Brazil of Archean/Paleoproterozoic age. Five groups of rock types all equilibrated in the granulite facies are identified in this region. They are: i) supracrustal and related rocks, ii) undifferentiated granulites, iii) hornblende bearing enderbite-charnockites, iv) hornblende free enderbite-charnockites, v) charnockites. The first group appears to be the oldest in the region as they form enclaves in the 2.9 Ga old undifferentiated granulites. The third and fourth group are enderbite-charnockites, whose protoliths constitute two series of calc-alkaline rocks, one titanium poor (hornblende free) and another titanium rich (hornblende bearing). U/Pb zircon SHRIMP dates indicate ages of formation at 2.81 Ga (hornblende free) and 2.69 Ga (hornblende bearing) for the two groups. The fifth group of rocks have charnockitic affinity and are present in the center of the Brejtes Dome. These rocks are also have calc-alkaline affinity, but show petrographic and geochemical characteristics distinct from those of other groups. Preliminary geochronological investigations by zircon Pb-Pb evaporation method yielded 2.6 Ga and 2.0 Ga for the charnockites from the inner core of the Brejtes Dome. These age data suggest that the circular structure was formed by the re-fusion of the 2.6 Ga old deep crustal material generating younger charnockites at 2.0 Ga. 相似文献
16.
Rebecca M. Flowers Samuel A. Bowring Kevin H. Mahan Michael L. Williams Ian S. Williams 《Contributions to Mineralogy and Petrology》2008,156(4):529-549
New U–Pb geochronology for an extensive exposure of high-pressure granulites in the East Lake Athabasca region of the western
Canadian shield is consistent with a history characterized by 2.55 Ga stabilization of cratonic lithosphere, 650 million years
of lower crustal residence and cratonic stability, and 1.9 Ga reactivation of the craton during lithospheric attenuation and
asthenospheric upwelling. High precision single-grain and fragment zircon data define distinctive discordia arrays between
2.55 and 1.9 Ga. U–Pb ion microprobe spot analyses yield a similar range of U–Pb dates with no obvious correlation between
date and cathodoluminescence zonation. We attribute the complex U–Pb zircon systematics to growth of the primary populations
during a 2.55 Ga high-pressure granulite facies event (~1.3 GPa, 850°C) recorded by the dominant mineral assemblage of the
mafic granulite gneisses, with subsequent zircon recrystallization and minor secondary zircon growth during a second high-pressure
granulite facies event (1.0 GPa, ~800°C) at 1.9 Ga. The occurrence of two discrete granulite facies metamorphic events in
the lower crust, separated by an interval of 650 million years that included isobaric cooling for at least some of this time,
suggests that the rocks resided at lower crustal depths until 1.9 Ga. We infer that this phase of lower crustal residence
and little tectonic activity is coincident with an extended period of cratonic stability. Detailed structural and thermochronological
datasets indicate that multistage unroofing of the lower crustal rocks occurred in the following 200 million years. Extended
lower crustal residence would logically be the history inferred for lower crust in most cratonic regions, but the unusual
aspect of the history in the East Lake Athabasca region is the subsequent lithospheric reactivation that initiated transport
of the lower crust to the surface. We suggest that a weakened strength profile related to the 1.9 Ga heating left the lithosphere
susceptible to far-field tectonic stresses from bounding orogens that drove the lower crustal exhumation. An ultimate return
to cratonic stability is responsible for the preservation of this extensive lower crustal exposure since 1.7 Ga. 相似文献
17.
R-P. Mnot A. Pêcher Y. Rolland J-J. Peucat A. Pelletier G. Duclaux S. Guillot 《Gondwana Research》2005,8(1):1-9
Geological maps of East Commonwealth Bay Unit (ECB), (Terre Adélie and Georges V Land, Antarctica) are presented with a summary of the main structural and metamorphic data for the region. The ECB unit was developed during Neoarchean_Paleoproterozoic event (at 2.5-2.42 Ga), with (i) granulite metamorphism at 9±1.5 kbar and 800±50°C in the lower crust section and amphibolite metamorphism (P=5 kbar, T=750°C) at the upper crustal levels; (ii) the lower crustal granulites were uplifted, and suffered local partial melting and retrogression to the amphibolite facies at 550±50°C_5 kbar. Granulites were extruded in the core of a crustal-scale anticlinal fold, but retrogressed only on the rims of the anticline. Crustal-scale folding, along with other structural features resulted from intense NE-SW shortening that prevailed during the Neoarchean orogenic cycle. Strike-slip and extensional motions were only minor components in that process; (iii) top-to-the-East thrusting and nappe piling had (at least locally) occurred under lower amphibolite to greenschist facies conditions. Finally, it seems that (iv) the Paleoproterozoic 1.7 Ga structural imprint may have only affected the rims of the Archean units. The tectonic context observed in the 1.7 Ga Cape Hunter phyllites features mainly an E-W shortening component and vertical extrusion. The eastern (Mertz) and western (Port Martin) parts of the Archean block were reactivated by localized dextral shearing. 相似文献
18.
造山带中成对出现的高压麻粒岩与榴辉岩及其地球动力学意义 总被引:18,自引:13,他引:5
在一些典型碰撞造山带中,高压麻粒岩与榴辉岩在空间和时间上密切相关,它们之间的关系对揭示碰撞造山带的造山过程和造山机制具有重要意义.本文以中国西部的南阿尔金、柴北缘及中部的北秦岭造山带为例,详细陈述了这3个地区榴辉岩和相关的高压麻粒岩的野外关系、变质演化和形成时代,目的是要建立大陆碰撞造山带中榴辉岩和相关高压麻粒岩形成的地球动力学背景模式.南阿尔金榴辉岩呈近东西向分布在江尕勒萨依,玉石矿沟一带,与含夕线石副片麻岩、花岗质片麻岩和少量大理岩构成榴辉岩一片麻岩单元,榴辉岩中含有柯石英假象,其峰期变质条件为P=2.8~3.0GPa,T=730~850℃,并在抬升过程中经历了角闪岩-麻粒岩相的叠加;大量年代学研究显示其峰期变质时代为485~500Ma.南阿尔金高压麻粒岩分布在巴什瓦克地区,包括高压基性麻粒岩和高压长英质麻粒岩,它们与超基性岩构成了一个大约5km宽的构造岩石单元,与周围角闪岩相的片麻岩为韧性剪切带接触.长英质麻粒岩和基性麻粒岩的峰期组合均具有蓝晶石和三元长石(已变成条纹长石),形成的温压条件为T=930~1020℃,P=1.8~2.5GPa,并在退变质过程中经历了中压麻粒岩相变质作用叠加.锆石SHRIMP测定显示巴什瓦克高压麻粒岩的峰期变质时代为493~497Ma.都兰地区的榴辉岩分布柴北缘HP-UHP变质带的东端,在榴辉岩和围岩副片麻岩中均发现有柯石英保存,形成的峰期温压条件为T=670~730℃和P=2.7~3.25GPa,退变质阶段经过了角闪岩相的叠加;榴辉岩相变质时代为420~450Mao都兰地区的高压麻粒岩分布在阿尔茨托山西部,高压麻粒岩包括基性麻粒岩长英质麻粒岩,基性麻粒岩的峰期矿物组合为Grt+Cpx+Pl±Ky±Zo+Rt±Qtz,长英质麻粒岩的峰期矿物组合为:Grt+Kf+Ky+Pl+Qtz.峰期变质条件为T=800~925℃,P=1.4~1.85GPa,退变质阶段经历了角闪岩-绿片岩的改造,高压麻粒岩的变质时代为420~450Ma.北秦岭榴辉岩分布在官坡-双槐树一带,榴辉岩的峰期变质组合为Grt+Omp±Phe+Qtz+Rt,所计算的峰期温压条件为T=680~770℃和P=2.25~2.65GPa,年代学数据显示榴辉岩的变质时代为500Ma左右.北秦岭高压麻粒岩分布在含榴辉岩单元的南侧松树沟一带,包括高压基性麻粒岩和高压长英质麻粒岩,与超基性岩在空间上密切伴生,高压麻粒岩的峰期温压条件为T=850~925℃,P=1.45~1.80GPa,锆石U-Pb年代学研究显示其峰期变质时代为485~507Ma.以上三个实例显示,出现在同一造山带、在空间上伴生的高压麻粒岩和榴辉岩有各自不同的变质演化历史,但榴辉岩中的榴辉岩相变质时代和相邻的高压麻粒岩中的高压麻粒岩相变质作用时代相同或相近,这种成对出现的榴辉岩和高压麻粒岩代表了它们同时形成在造山带中不同的构造环境中,即榴辉岩的形成于大陆俯冲带中,而高压麻粒岩可能形成在俯冲带之上增厚的大陆地壳根部. 相似文献
19.
A deep-level crustal section of the Cretaceous Kohistan arc is exposed in the northern part of the Jijal complex. The occurrence of mafic to ultramafic granulite-facies rocks exhibits the nature and metamorphic evolution of the lower crust. Mafic granulites are divided into two rock types: two-pyroxene granulite (orthopyroxene+clinopyroxene+plagioclase±quartz [1]); and garnet–clinopyroxene granulite (garnet+clinopyroxene+plagioclase+quartz [2]). Two-pyroxene granulite occurs in the northeastern part of the Jijal complex as a relict host rock of garnet–clinopyroxene granulite, where the orthopyroxene-rich host is transected by elongated patches and bands of garnet–clinopyroxene granulite. Garnet–clinopyroxene granulite, together with two-pyroxene granulite, has been partly replaced by amphibolite (hornblende±garnet+plagioclase+quartz [3]). The garnet-bearing assemblage [2] is expressed by a compression–dehydration reaction: hornblende+orthopyroxene+plagioclase=garnet+clinopyroxene+quartz+H2O↑. Subsequent amphibolitization to form the assemblage [3] is expressed by two hydration reactions: garnet+clinopyroxene+plagioclase+H2O=hornblende+quartz and plagioclase+hornblende+H2O=zoisite+chlorite+quartz. The mafic granulites include pod- and lens-shaped bodies of ultramafic granulites which consist of garnet hornblendite (garnet+hornblende+clinopyroxene [4]) associated with garnet clinopyroxenite, garnetite, and hornblendite. Field relation and comparisons in modal–chemical compositions between the mafic and ultramafic granulites indicate that the ultramafic granulites were originally intrusive rocks which dissected the protoliths of the mafic granulites and then have been metamorphosed simultaneously with the formation of garnet–clinopyroxene granulite. The results combined with isotopic ages reported elsewhere give the following tectonic constraints: (1) crustal thickening through the development of the Kohistan arc and the subsequent Kohistan–Asia collision caused the high-pressure granulite-facies metamorphism in the Jijal complex; (2) local amphibolitization of the mafic granulites occurred after the collision. 相似文献
20.
The occurrence of both Archean granulite terrains and granulite xenoliths in Cenozoic basalts from the Sino-Korean Craton (SKC) provides an ideal opportunity to define composition and evolution of continental lower crust of eastern China. The granulite xenoliths in Quaternary basanites from Nushan (southeastern SKC) show a basic-intermediate composition that is distinctly different from mafic granulites from Hannuoba (western SKC). They instead resemble the Archean granulite terrains in terms of mineral and whole rock compositions. Trace element modeling suggests that the “protoliths” of the Nushan granulites were likely subjected to fractional crystallization and assimilation of old crustal components. Zircon SHRIMP U-Pb dating shows at least two episodes in the formation of the lower crust at Nushan. The protoliths of the Nushan granulites were most likely formed at ca. 2.5 Ga and metamorphosed at 1.9 Ga. This late Archean crustal growth was followed by Mesozoic (∼140 Ma) basaltic underplating, which was probably coeval with the widespread thermo-tectonic lithospheric reactivation in eastern China. The Nushan granulites are therefore interpreted as dominantly derived from the late Archean crystalline basement and subordinately from the mafic layer that was accreted to the basement during late Mesozoic lithospheric thinning. The consistencies between the depth to seismic Moho and the depth to crust-mantle boundary, and between the calculated Vp (mostly < 7.0 km/s) for granulite xenoliths and the observed velocity structure strongly suggest no obvious high-velocity lowermost crust beneath Nushan and the granulite xenoliths as the dominant components in the lower crust at this locality. The modeled composition of the Nushan lower crust has SiO2 of ca. 52%, which is more basic than that at Hannuoba (SiO2 ≈ 58%, Liu et al., 2001). Such a compositional difference, in conjunction with contrasting age and seismic velocity structure of the lower crust at the two localities, highlights two fundamentally distinct tectonic domains in the SKC. The data presented in this study also yield implication for the origin of the compositional difference between granulite xenoliths and terrains. 相似文献