西天山特克斯一带双变质带特征

特克斯一带双变质带是西天山双变质带重要组成部分。对特克斯一带双变质带特征的详细观察和讨论,可能对整个西天山双变质带深入研究起到解剖麻雀的作用。低压相系变质岩是以堇青石片岩类为代表;高压相系变质岩是以蓝闪石片岩类为代表。在后继的收缩体制下,由于陆-陆碰撞作用,使能干性不同的层状变质岩叠置到一起,经过强烈纵向构造置换作用,使能干性较强的蓝闪石片岩类(包括大理岩)变成透镜状、似层状岩石,嵌在数量较多、能干性较弱的堇青片岩类里,构成双变质带混杂体。变质作用的时间约为晚志留世末。堇青石片岩类为低压相系角闪岩相岛弧型变质作用;蓝闪石片岩类属于高压相系低绿片岩相俯冲带型变质作用。     

藏北羌塘中部高压变质带中石榴子石白云母片岩的岩石学和变质特征

羌塘中部的高压变质带位于龙木错-双湖-澜沧江板块缝合带之上,由榴辉岩、蓝片岩和石榴子石白云母片岩组成,其形成过程对探讨板块缝合带的构造演化具有重要意义。以其中的石榴子石白云母片岩为研究对象,通过岩相学研究并结合电子探针成分分析,认为石榴子石白云母片岩中的石榴子石具有多期次变质结晶的特征,保留了岩石多期次变质的信息。结合岩石组构特征,最终确定石榴子石白云母片岩至少经历了3期次的变质作用。第一、二期均为绿片岩相,当时岩石不具定向构造且未达到高压;第三期为低温高压蓝片岩相变质作用,与区域上蓝片岩的形成及榴辉岩的蓝片岩相退变质作用大体同时,该期变质变形作用形成了岩石的片理,最终成为石榴子石白云母片岩,变质作用时代为218Ma左右。     

羌塘中部高压变质带的退变质作用及其构造侵位

羌塘中部的高压变质带主要由榴辉岩、石榴石白云母片岩和蓝片岩等组成,它们在遭受高压变质作用之后折返,构造侵位于晚古生代展金组地层中,二者以韧性变形带为接触边界.本文以高压变质带中的榴辉岩和韧性变形带为研究对象,讨论了高压变质带折返过程中的退变质作用特征及折返时代.研究表明,榴辉岩在高峰期变质作用之后的折返过程中经历了由榴辉岩相→蓝片岩相→绿帘角闪岩相的退变质作用演化过程;在高压变质带构造侵位过程形成的韧性变形带中,白云母石英片岩的白云母40Ar-39Ar坪年龄为219±2Ma.高压变质带在219Ma左右构造侵位于展金组地层中,并于214Ma之前最终抬升出露地表.     

蓝片岩与绿片岩共存:龙江岩系构造演化的新证据

本文从岩石及矿物的变质—变形关系和化学成分研究证明,龙江岩系①中蓝片岩与绿片岩的共存不是单一变质事件的产物,而是构造变动和不连续变质作用叠加的结果。早期蓝片岩形成在一种高压低温,高氧逸度环境。后经构造变动,转变为地热梯度较高的变形环境中,遭受韧性变形和以增温为主的绿片岩相变质作用的叠加。其间,钠质闪石向钠钙质闪石的转变,代表一种不连续的增温事件,而钠钙质闪石向钙质闪石的转变反映一种连续的增温过程。     

牡丹江地区蓝片岩的地球化学特征及其大地构造意义

牡丹江地区的蓝片岩分布于牡丹江东部的椅子圈、磨刀石等地。野外调研表明：牡丹江蓝片岩主要呈透镜体状或构造残片状发育在长英质片岩中,并部分可见变余枕状构造和气孔状构造;主量元素岩石化学分析得到这些蓝片岩为亚碱性玄武岩组合;稀土元素标准化配分曲线与洋中脊环境（E-MORB）配分曲线一致;微量元素蛛网图曲线也与E-MORB一致,部分易活动元素（Ba,Sr等）一定程度的分异应与海相玄武岩形成时遭受海水蚀变或后期绿片岩相变质有关。代表性蓝片岩的地球化学特征表明,牡丹江地区蓝片岩的原岩形成于大洋板块内的洋中脊环境。因此,黑龙江蓝片岩应为佳木斯地体向西与松嫩地块之间碰撞拼贴而形成的具有蛇绿岩性质的高压变质带;而目前保存下来的蓝片岩带应为遭受高压变质作用并仰冲到佳木斯地块之上的大规模增生杂岩带的残余部分。结合作者近年取得的牡丹江地区蓝片岩SHRIMP锆石年龄210~250 Ma和变质云母等单矿物180~190 Ma的年代学证据,证明它们为晚二叠世-晚三叠世的玄武岩经过印支期前后高压变质而形成。黑龙江蓝片岩带的形成是印支期前后古亚洲构造域向环太平洋构造域转换的结果,即黑龙江杂岩带为典型的构造转换带-古亚洲洋构造拼合的结束和环太平洋构造带俯冲开始的标志。     

中国蓝片岩带的时空分布、地质特征和成因

本文主要介绍了中国蓝片岩的时空分布、一般地质特征和成因。内容主要包括以下6个方面:一是当前中国蓝片岩的研究概况和重要进展;二是蓝片岩、蓝闪片岩和蓝片岩相名词的讨论;三是对17个蓝片岩带的一般地质特征(主要包括原岩性质、岩石矿物共生组合,p-t条件,变质时代及赋存的大地构造背景等)进行描述;四是讨论蓝片岩带的成因,并提出深俯冲-陆陆碰撞型和深俯冲-洋壳碰撞两个模式;五是总结了几点蓝片岩带综合地质特征;六是提出了蓝片岩带研究中存在的6个地质科学问题,建议进一步加强考察与研究。     

黑龙江依兰地区蓝片岩相变质作用及其演化

依兰地区蓝片岩作为黑龙江杂岩的重要组成部分,其变质作用演化问题一直存在较大争议。本文通过对依兰地区蓝片岩的岩相学及矿物微区化学成分的研究,并运用PERPLE_X软件,在Na_2O-CaO-K_2O-MnO-FeO-MgO-Al_2O_3-SiO_2-H_2O-TiO_2-O(Fe_2O_3)(NCKMnFMASHTO)体系下对石榴石冻蓝闪石片岩(g-brs-wnc-act-phn-chl-ep-ab-stlp)、绿泥绿帘蓝闪石片岩(gl-brs-wnc-act-chl-ep-stlp)和白云母蓝闪石片岩(gl-wnc-phn-ab-ep-chl-sph)进行了相平衡模拟,并分别获得了500~525℃/1.14~1.2GPa、480℃/1.4GPa、450~500℃/0.95~1.2GPa峰期变质作用的温压条件,其峰期变质级别都达到了绿帘-蓝片岩相。结合前人发表的地球化学和年代学数据,建立了蓝片岩相岩石的顺时针变质演化P-T轨迹。研究区蓝片岩的形成标志着新生洋壳的俯冲作用,同时代表古亚洲洋构造域的结束和环太平洋构造域的开始。相平衡模拟中,P-T轨迹记录了峰期前温压条件递增的过程,温度峰期与压力峰期同时到达,说明蓝片岩相变质作用是在俯冲过程中实现的,而不是折返过程中达到的。减压阶段的轨迹近于平行追溯进变质轨迹,揭示与进变质过程相似的地热体制下(11～14℃/km),相对缓慢的抬升过程     

牡丹江地区蓝片岩中脉状青铝内石^40Ar—^39Ar年龄及其地质意义

对穆棱县的磨刀石、椅子圈地区的蓝片岩研究，确定其经受过三期叠加变质作用：第一期为蓝片岩相变质作用：第二期为蓝闪绿片岩相变质作用；第三期为受断裂构造控制的动力变质作用，形成脉状青铝闪石、钠长石等变质矿物。通过对脉状产出的青铝闪石＾４０Ａｒ－＾３９Ａｒ年龄测定，获得较好的年龄谱，坪年龄为１５４．７±０．７Ｍａ。此年龄表明了该期变质作用与敦－密断裂发生大规模左行走滑有关，由于大型走滑断裂造成局部构造超高     

牡丹江地区蓝片岩中脉状青铝闪石~（40）Ar—~（39）Ar年龄及其地质意义

对穆棱县的磨刀石、椅子圈地区的蓝片岩研究，确定其经受过三期叠加变质作用：第一期为蓝片岩相变质作用；第二期为蓝闪绿片岩相变质作用；第三期为受断裂构造控制的动力变质作用，形成脉状青铝闪石、钠长石等变质矿物。通过对脉状产出的青铝闪石￣（４０）Ａｒ—￣（３９）Ａｒ年龄测定，获得较好的年龄谱，坪年龄为１５４．７±０．７Ｍａ。此年龄表明了该期变质作用与敦—密断裂发生大规模左行走滑有关，由于大型走滑断裂造成局部构造超高压，诱发了原有的蓝片岩中流体活化，而形成青铝闪石、钠长石、绿帘石等矿物组成的脉体沿剪切面分布。     

新疆南天山高压变质岩石的抬升机制

对南天山蓝片岩的变质作用p-T-t轨迹、蓝片岩和相关岩石的构造变形特征以及区域地质特征的综合研究表明,南天山高压变质岩石经历了两个抬升阶段。早期阶段,蓝片岩在增生楔下部的下地壳深处滞留了约100Ma,仅因浮力作用发生轻微抬升,速率约0.05-0.1mm/a。晚期阶段,推覆作用和剥蚀作用快速抬升蓝片岩浅构造层次,速率可能大于1-2mm/a,以致保存蓝闪绿片岩相矿物组合。     

甘肃玉门昌马地区的蓝闪片岩

蓝闪片岩产于一套含放射虫硅质岩、硅质大理岩、板岩、变质基性火山岩中,与此相伴的超基性岩块,以一系列向南逆冲的断片产出。蓝闪片岩中的蓝闪石往往和黑硬绿泥石、钠长石、绿泥石以及钠钙闪石(蓝透闪石、冻蓝闪石等)、钙闪石(阳起石等)共存。据钠角闪石、绿泥石计算的生成压力是0.65GPa至0.8GPa,略大于美国佛兰西斯科的瓦尔德溪蓝片岩中该矿物对生成的压力。稀土元素分析证明蓝片岩的原岩是典型洋底(中脊)玄武岩和岛弧玄武岩,这是蓝片岩沟-弧俯冲-碰撞的证据之一。     

羌塘中部高压变质带的形成过程

羌塘中部高压变质带由榴辉岩、石榴石白云母片岩和蓝片岩等组成,与蛇绿混杂岩、晚古生代浅变质地层岩片等共同构成了龙木错-双湖板块缝合带这一构造混杂岩带,是伴随古特提斯洋闭合的深俯冲作用及后期构造作用的产物。通过对其野外地质特征、不同岩石类型岩石学、矿物学以及同位素年代学等的研究,确认榴辉岩和石榴石白云母片岩在早期分别经历了各自的形成过程,在榴辉岩形成之后的折返过程中二者共同构成了高压变质带,并且在折返过程中榴辉岩发生蓝片岩相退变质作用,同时导致了带内蓝片岩的形成。同位素年代学研究结果表明,龙木错-双湖板块缝合带闭合过程中的榴辉岩相变质作用发生于240Ma左右,折返过程中的蓝片岩相退变质作用及蓝片岩的形成应在220～200Ma,高压变质带最终在214Ma之前抬升出露地表。     

蓝片岩及其有关高压变质带研究的新进展

通常认为蓝片岩主要分布在中新生代的造山带中，其成因与大洋板块的俯冲作用有关；而大陆上的蓝片岩一般与蛇绿岩和混杂岩伴生代表了古板块的缝合线。但近来研究发现，蓝片岩的矿物组合、时空分布和原岩建造多种多样。归纳起来可分为两种类型：科迪勒拉型和大陆内部型。不同的蓝片岩是在不同的大地构造环境下由不同的成因机制形成的，还是仅在洋壳俯冲环境中，由于不同的物质卷入俯冲带，引起俯冲过程中动力学机制变化形成的，是当前蓝片岩研究中至为重要的问题。     

甘肃玉门昌马地区的蓝闪片岩

蓝闪片岩产于一套含放射虫硅质岩、硅质大理岩、板岩、变质基性火山岩中,与此相伴的超基性岩块,以一系列向南逆冲的断片产出。蓝闪片岩中的蓝闪石往往和黑硬绿泥石、钠长石、绿泥石以及钠钙闪石(蓝透闪石、冻蓝闪石等)、钙闪石(阳起石等)共存。据钠角闪石、绿泥石计算的生成压力是0.65GPa至0.8GPa,略大于美国佛兰西斯科的瓦尔德溪蓝片岩中该矿物对生成的压力。稀土元素分析证明蓝片岩的原岩是典型洋底(中脊)玄武岩和岛弧玄武岩,这是蓝片岩沟-弧俯冲-碰撞的证据之一。     

北祁连山硬柱石蓝片岩p-T条件相平衡计算及其岩石学意义

北祁连硬柱石蓝片岩主要分布在甘肃省肃南县九个泉一带,是目前中国唯一报道的、确切地含有硬柱石的蓝片岩。文中在详细的岩石学和矿物学研究基础上,根据矿物共生组合的不同,将北祁连低温蓝片岩进一步划分为绿纤石蓝片岩、硬柱石蓝片岩和绿帘石蓝片岩。绿纤石蓝片岩的特征变质矿物组合为蓝闪石(>40%)+绿纤石(30%)+绿泥石(10%)+钠长石(8%)+石英(5%)+硬柱石(<3%)±方解石/文石(<1%)。硬柱石蓝片岩的矿物组合为蓝闪石(35%~40%)+硬柱石(35%~40%)+绿泥石(10%)+钠长石(10%)+石榴石(1%~2%)+黝帘石/斜黝帘石(<2%)+石英(<1%),副矿物有磷灰石和榍石,总含量小于2%。绿帘石蓝片岩的矿物组合为蓝闪石(30%~35%)+黝帘石/斜黝帘石/绿帘石(~30%)+绿泥石(15%)+钠长石(15%)+石榴石(2%)+石英(<2%),副矿物有金红石、磷灰石和磁铁矿,总含量小于2%。利用矿物内部一致性热力学数据和Domino/Theriak软件计算了这三种类型的蓝片岩形成的峰期温压条件,它们分别是绿纤石蓝片岩为320~350℃,0.75~0.85GPa;硬柱石蓝片岩为335~355℃,0.8~0.95GPa;绿帘石蓝片岩为345~375℃;0.75~0.85GPa。北祁连低温蓝片岩带由硬柱石蓝片岩相到绿帘石蓝片岩相的转化代表了俯冲变质过程中的递进变质过程。     

Aragonite from Mulanshan Glaucophane Schist: Implications for Regional Evolution of Southwestern Dabie Mountains, Central China

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SOME TRENDS IN THE STUDY OF CARBONATE SEDIMENTS IN THE FEDERAL REPUBLIC OF GERMANY

A stratigraphically coherent blueschist terrane near Aksu in northwestern China is unconformably overlain by unmetamorphosed sedimentary rocks of Sinian age (～600 to 800 Ma). The pre-Sinian metamorphic rocks, termed the Aksu Group, were derived from shales, sandstones, basaltic volcanic rocks, and minor cherty sediments. They have undergone multi-stage deformation and transitional blueschist/greenschist-facies metamorphism, and consist of strongly foliated chlorite-stilpnomelane-graphite schist, stilpnomelane-phengite psammitic schist, greenschist, blueschist, and minor quartzite, metachert, and meta-ironstone. Metamorphic minerals of basaltic blueschists include crossitic amphibole, epidote, chlorite, albite, quartz, and actinolite. Mineral parageneses and compositions of sodic amphibole suggest blueschist facies recrystallization at about 4 to 6 kbar and 300 to 400° C. Many thin diabasic dikes cut the Aksu Group; they are characterized by high alkali, TiO₂, and P₂O₅ contents and possess geochemical characteristics of within-plate basalts; some of these diabasic rocks contain sodic clinopyroxene and amphibole as primary phases and have minor pumpellyite, albite, epidote, chlorite, and calcite as the prehnite/pumpellyite-facies metamorphic assemblage. This prehnite/pumpellyite-facies overprint did not affect the host rocks of the blueschist-facies lithologies.

K-Ar and Rb-Sr ages of phengite and whole rocks from pelitic schists are ～690 to 728 Ma, and a ⁴⁰Ar/³⁹Ar age of crossite from the blueschist is 754 Ma. The basal conglomerate of the overlying Sinian to Eocambrian sedimentary succession contains clasts of both the blueschist and cross-cutting dike rocks, clearly demonstrating that conditions required for blueschist-facies metamorphism were attained and ceased at least 700 Ma. The northward-increasing metamorphic grade of the small blueschist terrane may reflect northward subduction of an accretionary complex beyond the northern edge of the Tarim craton. Abundant subparallel diabasic dikes indicate a subsequent period of Pre-Sinian rifting and diabasic intrusion along the northern margin of Tarim; a Sinian siliciclastic and carbonate sequence was deposited unconformably atop the Aksu Group and associated diabase dikes.     

Alpine metamorphism of Hercynian hornblende granodiorite beneath the blueschist facies schistes lustrés nappe of NE Corsica

Abstract The Hercynian granitic basement which forms the Tenda Massif in NE Corsica represents part of the leading edge of the European Plate during middle-to-late Cretaceous (Eoalpine) high P metamorphism. The metamorphism of this basement, induced by the overthrusting of a blueschist facies (schistes lustrés) nappe, was confined to a major ductile shear zone (c. 1000m thick) within which deformation increases upwards towards the overlying nappe. Metamorphism within the basement mostly records lower blueschist facies conditions (crossite + epidote) except near the base of the shear zone where the greenschist facies assemblage albite + actinolitic amphibole has developed instead of crossite. Study of the primary mafic phase breakdown reactions within hornblende granodiorite reveals the following metamorphic zonation. Zone 1: biotite to chlorite. Towards zone 2: biotite to phengite. Zone 2: Hornblende to actinolitic Ca-amphibole + albite + sphene, and biotite to actinolitic Ca-amphibole + albite + phengite + Ti-ore + epidote. Zone 3: Hornblende to crossite + low Ti-biotite + phengite + sphene, and biotite to crossite + low Ti-biotite + phengite + Ti-ore + sphene ± epidote. P-T conditions at the base of the shear zone are estimated to have been 390-490°C at 600-900 M Pa (6-9kbar) and the Corsican basement is therefore deduced to have been buried to 20-30 km during metamorphism. This relatively shallow metamorphism contrasts with some other areas in the Western Alps where the Eoalpine event apparently buried the European continental crust to depths of 80 km or more. As there is no evidence for a long history of blueschist facies metamorphism prior to the involvement of the European continent, it is deduced that the Eoalpine blueschists were produced during the collision of the Insubric plate with Europe, rather than during Tethyan intraoceanic subduction. Coherent blueschist terrains such as the schistes lustres probably record buovant feature collision and obduction tectonics rather than any preceding oceanic subduction.     

Zircon U–Pb Geochronology of Baiyingaolao Formation from the Hadayingzi Region in the southern Great Xing’an Range, Northeast China

Blueschists in the Yilan area, Heilongjiang Province, are known as important parts of the Heilongjiang Complex. However, their metamorphic evolution history is still unclear. Petrographical, and mineral chemical investigations on the blueschists from the Yilan area are carried out in this study. P‐T pseudosections are calculated in the system Na₂O‐CaO‐K₂O‐MnO‐FeO‐MgO‐Al₂O₃‐SiO₂‐H₂O‐TiO₂‐O (Fe₂O₃) (NCKMnFMASHTO) with the PERPLE_X software for three blueschist samples. Peak metamorphic conditions are estimated to be 500‐525°C, 1.14‐1.2 GPa for garnet‐barroisite schist (g‐brs‐wnc‐act‐phn‐chl‐ep‐ab‐stlp); 480°C, 1.4 GPa for chlorite‐epidote glaucophane schist (gl‐brs‐wnc‐act‐chl‐ep‐stlp) and 450‐500°C, 0.95‐1.2 GPa for phengite‐glaucophane schist (gl‐wnc‐phn‐ab‐ep‐chl‐sph), which indicate that they all underwent peak metamorphism in the limit epidote‐blueschist facies conditions. Combined with the previously reported geochemical and geochronological data, the clockwise P‐T paths of the blueschists are constructed. The formation of blueschists in the study area marks the young oceanic crust subduction, and represents the final closure of the Paleo‐Asian Ocean and the beginning of the Paleo‐Pacific tectonic system. The P‐T pseudosection recorded the P‐T increasing process before the metamorphic peak and that the maximum temperature was coincident with the maximum pressure in the process, which indicates that the epidote‐blueschist facies conditions implemented in the process of subduction, rather than exhumation. The retrograde trajectory nearly coincidently retraced the prograde trajectory, which represents the similar geothermal gradient (11‐14°C/km) in the subduction and the relatively slow exhumation process.