东喜马拉雅构造结南迦巴瓦岩群的解体

通过对研究区南迦巴瓦岩群的大比例尺填图工作,根据南迦巴瓦岩群的原岩建造、变质程度的不同、变形样式的差异,将其解体为在区域上具有可填性3套岩石组合——直白岩组、派乡岩组和多雄拉混合岩,三者之间均以构造面接触。     

东喜马拉雅构造结南迦巴瓦岩群花岗质片麻岩的初步研究

野外地质填图和研究发现,东喜马拉雅构造结高喜马拉雅结晶岩系中有古老的花岗岩侵入,并在鲁霞地区圈定了9个花岗质侵入体。古老的花岗质岩石主要侵位于南迦巴瓦岩群直白岩组中,与南迦巴瓦岩群一起经历了麻粒岩相变质作用而形成花岗质片麻岩套。岩石类型有花岗闪长质片麻岩、黑云母花岗质片麻岩、闪长质片麻岩等。岩石化学研究表明这些花岗片麻岩套具“S”型特征,可能有深部幔源物质的加入。花岗岩形成深度在2～5km之间,侵位时代为552～525 Ma,为新元古代晚期,属泛非期陆内演化阶段的产物。高喜马拉雅地区在元古宙末期形成了结晶基底。     

大陆碰撞造山带的流体成分与演化:东喜马拉雅构造结南迦巴瓦岩群高压麻粒岩的流体包裹体研究

位于喜马拉雅东构造结的南迦巴瓦岩群经历了高压麻粒岩相、中压麻粒岩相和角闪岩相三期变质作用.在高压麻粒岩中含有复杂的流体包裹体类型,按照捕获先后顺序有:H2O-CO2±CH4包裹体(Ⅰ型);CO2±CH4±N2包裹体(Ⅱ型);高盐度多相包裹体(Ш型);中.低盐度H2O包裹体(Ⅳ型)和极低密度气体包裹体或"空"包裹体(Ⅴ型).在基性麻粒岩中,被石榴石包裹石英中孤立分布的H2O-CO2 4-CH4包裹体,以及部分沿石榴石晶内裂隙分布的H2-CO2±CH4和H2O包裹体轨迹未穿过围绕石榴石的辉石 斜长石后成合晶冠状体,表明它们有可能是在麻粒岩相变质阶段捕获的.然而,所有流体包裹体的等容线均从麻粒岩相变质峰期P-T区间下方通过,说明麻粒岩相变质峰期捕获的包裹体均受到了不同程度的改造,包括部分爆裂、渗漏和流体-矿物相互作用等.现存的富CO2流体包裹体均具有较低密度,并且往往含有明显数量CH4和N2组分,不可能是麻粒岩相变质峰期捕获的包裹体.根据富CO2包裹体与具有不同相比的H2-CO2包裹体共存推测,大部分CO2包裹体是通过H2O-CO2包裹体中H2O的选择性泄漏而形成的.Ⅲ型高盐度盐水包裹体很可能是角闪岩相退变质过程中捕获的,因其等容线与退变质轨迹近于平行,这些包裹体很可能保存了其在角闪岩相阶段捕获时的原生物理化学特征.沿矿物颗粒裂隙分布的大量Ⅳ型和Ⅴ型包裹体,应该是角闪岩相或更晚期形成的次生包裹体,代表了浅成(近地表)环境的循环流体.与世界许多地区麻粒岩相岩石普遍舍高密度纯CO2流体包裹体不同,南迦巴瓦岩群高压麻粒岩以富含H2O-CO4±CH4和H2O包裹体为特征,这可能与高压麻粒岩与高温麻粒岩产出于不同的构造环境和经历的退变质轨迹有关.     

喜马拉雅造山带东构造结南迦巴瓦岩群地质年代学和前寒武纪构造演化

位于喜马拉雅造山带东构造结,印度-雅鲁藏布江缝合带以南的南迦巴瓦岩群经历了高压变质作用和强烈的部分熔融与混合岩化作用.本文选择广泛分布的长英质片麻岩进行了岩石学和年代学研究.除个别岩石保存了由石榴石 蓝晶石 三元长石 石英组成的高压泥质麻粒岩相变质矿物组合以外,大多数片麻岩具有角闪岩相变质矿物组合,它们的原岩包括闪长岩和花岗闪长岩,并具有岩浆弧花岗岩的化学成分特征.片麻岩中的锆石普遍具有核-边结构.SARIMP和LA-ICP-MS原位分析表明,锆石的边缘给出了古生代至新生代的多期变质和岩浆事件年龄(500～10Ma),而锆石的核部给出了前寒武纪年龄,但主要集中在～2500Ma,～1800Ma,～1600Ma和～1000Ma.所分析的锆石区域具有明显的岩浆结晶环带和高的Th/U比值,表明它们所指示的是多期岩浆活动事件年代.这些年代峰值与整个高喜马拉雅结晶杂岩及印度陆块所获得的前寒武纪构造热事件年龄及分布特征基本上可以对比.因此,我们认为南迦巴瓦岩群及高喜马拉雅结晶杂岩的原岩是由新太古代至新元古代形成的多期岩浆岩组成,并作为印度陆块的一部分经历了Columbia、Rodinia和Gondwana超大陆的形成与裂解过程,以及喜马拉雅期的区域变质与岩浆作用再造.     

南迦巴瓦地区东喜马拉雅构造结印度与欧亚大陆古新世初期碰撞的构造及年代学证据

南迦巴瓦地区东喜马拉雅构造结为一由边界断裂围限的强烈变形变质地体,其东、西边界分别为左行为主的东久——米林断裂和右行的阿尼桥断裂,北边界由一系列北西向断裂组成,沿边界分布雅鲁藏布江缝合带及日喀则群弧前沉积的残余。构造结变质地体为印度大陆高喜马拉雅岩系的角闪岩相——麻粒岩相正负片麻岩,构造结外侧为欧亚大陆岩系。构造结西边界的东久——米林断裂为——北东走向左行剪切带,主要由强烈剪切变形形成的糜棱状岩石组成,运动性质为北西盘上升的左行逆冲;构造结内部构造形态为南南西向逆冲推覆构造体系。边界断裂的走滑与构造结内部的缩短运动形式协调一致,     

喜马拉雅东构造结地区雅鲁藏布江蛇绿岩地质年代学研究

雅鲁藏布江结合带在东构造结地区形成弧形展布的蛇绿混杂带,此前对该带蛇绿岩的地球化学特征和成因已有研究,但年代学研究十分薄弱.本文报道对该带蛇绿岩的地质年代学研究成果.从变玄武岩和变辉长岩中分选出两类锆石.一类锆石为自形的柱状双锥,具有清晰的同心韵律环带,较高的Th/U比值(主要为0.63～2.79),SHRIMP Ⅱ测...     

秦岭岩群古生代构造变形分析

秦岭岩群是秦岭造山带中最古老的地体之一,其强烈的构造变形记录了秦岭造山带的形成和演化信息。本文在野外构造调查的基础上、结合显微构造变形分析和锆石U-Pb定年,对秦岭岩群进行了构造变形解析及年代学研究,结果显示秦岭岩群古生代构造变形表现为由东向西的斜向挤出抬升,其构造变形时间为426.7±5.8 Ma～395.7±7.4 Ma。该期构造变形温度为480℃～560℃,对应变质相为高绿片岩相—低角闪岩相,差异应力为20.19～56.54 MPa,应变速率为1.822 81×10^-13 s^-1～5.621 02×10^-13 s^-1,付林参数为0.29～0.47,涡度值为0.57～0.75。综合前人研究及本次构造变形分析,认为秦岭岩群在扬子板块与华北板块斜向汇聚背景下经历了由东向西的斜向挤出抬升。     

东喜马拉雅构造结多雄拉混合岩和花岗片麻岩锆石U-Pb年龄及其地质意义

位于东喜马拉雅构造结的南迦巴瓦岩群是研究喜马拉雅构造带基底演化的重要对象之一.在构造样式上,南迦巴瓦岩群为一个背形构造,该背形构造的核部由多雄拉混合岩和花岗片麻岩组成.本文开展了南迦巴瓦岩群多雄拉混合岩的锆石LA-ICP-MS U-Pb定年研究.结果表明.多雄拉混合岩深色体的原岩形成年龄为1759±10Ma,浅色体的形成年龄为1594±13Ma,代表发生混合岩化的年龄.另外,一个多雄拉花岗片麻岩的原岩形成年龄为1583±6Ma,该年龄在误差范围内与区域发生混合岩化作用的时代相近,表明在混合岩化过程中存在着一定程度的地壳深熔作用.区域对比表明,低喜马拉雅和高喜马拉雅构造单元内存在着明显不同的构造一岩浆事件,其中低喜马拉雅构造单元广泛存在1.6～1.8Ga的构造-岩浆事件.与之相对比,多雄拉混合岩和花岗片麻岩的锆石U-Pb年代学说明南迦巴瓦岩群核部应属于低喜马拉雅结晶岩系,而明显不同于高喜马拉雅结晶岩系,这与西喜马拉雅构造结相似,表明东喜马拉雅构造结与西喜马拉雅构造结有着相似的地质演化.     

东喜马拉雅构造结南迦巴瓦群高压麻粒岩中含石榴石花岗岩脉锆石SHRIMP U-Pb定年及其与折返作用

东喜马拉雅构造结核部的南迦巴瓦群是经历了高压麻粒岩相峰期变质、角闪岩相退变质和强烈混合岩化作用形成的以含有高压麻粒岩透镜体或夹层为特色的变质岩组合。地质地球化学研究表明产于退变质高压麻粒岩中的含石榴石花岗岩脉具有高钾、富铝、轻稀土强烈富集、分馏程度很高、重稀土相对亏损、Eu强烈亏损、大离子亲石元素及放射性元素相对原始地幔值强烈富集、Rb/Sr1.4的特征。利用花岗岩的主要成分及锆的含量估算的岩浆初始温度为792～801℃,略低于南迦巴瓦群的峰期变质温度850℃。锆石SHRIMPU-Pb定年结果显示锆石核部年龄集中在519～525Ma之间,揭示出印度地块经历泛非期构造运动改造的痕迹。锆石边部主要存在39～44Ma、24～25Ma和7.3Ma三个年龄段,前者代表了花岗岩浆的侵位时代,第二个年龄段是对MCT和STDS构造热事件改造的反映,后者揭示出构造-浅表反馈作用的信息。说明含石榴石花岗岩脉是在南迦巴瓦群折返过程中近等温降压条件下地壳岩石发生"干"深熔作用形成的高钾过铝质钙碱性花岗岩,以及南迦巴瓦群在经历峰期变质作用后很快就开始折返,并在后碰撞过程中经历了藏南拆离系(STDS)和主中央冲断带(MCT)构造事件及后期构造-浅表反馈作用的影响。     

喜马拉雅早古生代造山作用:来自尼泊尔帕朗花岗质片麻岩锆石U-Pb年代学和Hf同位素证据

尼泊尔帕朗花岗质片麻岩是加德满都逆冲席体的一部分,其主要矿物组成为石英、斜长石、钾长石、微斜长石和白云母。片麻岩中的锆石发育核-边结构,由继承碎屑锆石核和韵律环带的岩浆锆石边组成。LAICP-MS U-Pb定年结果显示,边部岩浆锆石的加权平均年龄为(485.5±1.4)Ma和(455.1±3.1)Ma,指示片麻岩原岩为早古生代早期的花岗岩,并记录了两期岩浆作用。锆石边部εHf(t)值变化范围为-8.7~-3.5,Hf同位素两阶段模式年龄TCDM为2.01~1.69Ga,结合岩石学特征并对比大喜马拉雅和小喜马拉雅变质沉积岩的Hf同位素成分,认为原岩花岗岩来自大喜马拉雅变泥质岩的部分熔融。帕朗花岗质片麻岩的研究结果和现有的年代学数据表明,喜马拉雅地区存在早古生代造山事件,这一事件可与相邻的拉萨地体、羌塘地体以及青藏高原东南缘的保山-腾冲地体内同一时代的构造事件对比,是早古生代早期原特提斯洋岩石圈沿冈瓦纳大陆北缘俯冲的安第斯型造山作用的产物,而与冈瓦纳大陆内部块体聚合过程中陆-陆碰撞的泛非造山作用无关。     

Petrology and geochronology of the Namche Barwa Complex in the eastern Himalayan syntaxis, Tibet: Constraints on the origin and evolution of the north-eastern margin of the Indian Craton

The Namche Barwa Complex (NBC) in the eastern Himalayan syntaxis, south Tibet, is generally interpreted as the north-eastern extremity of the exposed Greater Himalayan Sequence, comprising Neoproterozoic to early Paleozoic sedimentary strata along the northern margin of the Indian continent. Field and petrological investigations indicate that the NBC consists mainly of orthogneiss, paragneiss, amphibolites and calc-silicate rocks. U-Pb zircon data demonstrate that the protoliths of the orthogneiss formed during late Paleoproterozoic at ca. 1610 Ma and also in early Paleozoic at ca. 490-500 Ma. The amphibolites were derived from mafic magmatic rocks formed during 1645 to 1590 Ma. Zircons in the paragneisses have highly variable inherited zircon ages ranging from the Neoarchean to early Paleozoic, with four major age populations of 2490 Ma, 1640 Ma, 990 Ma and 480 Ma. The calc-silicate rock has zircons with early Paleozoic metamorphic age of 538 Ma. Almost all the rocks of the NBC have been metamorphosed during Cenozoic with the metamorphic zircon U-Pb ages ranging from 8 to 30 Ma and a peak at 23 Ma. These, together with previous results suggest that the NBC was originally derived from an Andean-type orogeny following the Columbia supercontinent assembly, and experienced multiple reworking during the Grenvillian, Pan-African and Himalayan orogenies. We conclude that the NBC in the eastern Himalayan syntaxis was derived from different provenance and tectonic setting as compared to those of the Greater Himalayan Sequence which constitutes the high-grade metamorphic core of the western and central Himalayan orogenic belt. We thus infer that the NBC was originally part of the eastern segment of the Central Indian Tectonic Zone.     

西藏南部南迦巴瓦地区中新世-上新世地壳深熔作用

位于喜马拉雅东构造结的南迦巴瓦地块经历了复杂的构造变形、强烈的变质和深熔作用,是研究碰撞造山过程中地壳深熔作用的重要对象。完整地厘定新生代晚期岩浆作用期次对于揭示南迦巴瓦地区的构造演化历史和深部过程具有重要意义。南迦巴瓦地块3件淡色花岗岩样品的锆石U-Pb定年结果显示该地块经历了11.30±0.16Ma和2.59±0.04Ma两期地壳深熔作用,可能与南迦巴瓦地块晚新生代快速隆升和剥蚀相关。南迦巴瓦地块保存了大量的~11Ma变质作用和地壳深熔作用记录指示该时间段为构造活动剧烈期。上新世晚期的淡色花岗岩表明,穹窿的隆升和剥蚀所导致的岩浆作用至少持续到了~2.59Ma,代表了南迦巴瓦地区一次年轻的构造岩浆事件。

     

Paleogene crustal anatexis and metamorphism in Lhasa terrane, eastern Himalayan syntaxis: Evidence from U-Pb zircon ages and Hf isotopic compositions of the Nyingchi Complex

In the eastern Himalayan syntaxis, the southern Lhasa terrane is dominated by middle- to high-grade metamorphic rocks (Nyingchi Complex), which are intruded by felsic melts. U-Pb zircon dating and zircon Hf isotopic composition of these metamorphic and magmatic rocks provide important constraints on the tectono-thermal evolution of the Lhasa terrane during convergent process between Indian and Asian continents. U-Pb zircon data for an orthogneiss intruding the Nyingchi Complex yield a protolith magma crystallization age of 83.4 ± 1.2 Ma, with metamorphic ages of 65-46 Ma. This orthogneiss is characterized by positive ε_Hf (t) values of + 8.3 and young Hf model ages of ~ 0.6 Ga, indicating a derivation primarily from a depleted-mantle or juvenile crustal source. Zircons from a quartz diorite yield a magma crystallization age of 63.1 ± 0.6 Ma, with ε_Hf (t) values of − 8.2 to − 2.7, suggesting that this magma was sourced from partial melting of older crustal materials. Zircon cores from a foliated biotite granite show ages ranging from 347 to 2690 Ma, with age peaks at 347-403 Ma, 461-648 Ma and 1013-1183 Ma; their zircon ε_Hf (t) values range from − 30.6 to + 6.9. Both the U-Pb ages and Hf isotopic composition of the zircon cores are similar to those of detrital zircons from the Nyingchi Complex paragneiss, implying that the granite was derived from anatexis of the Nyingchi Complex metasediments. The zircon rims from the granite indicate crustal anatexis at 64.4 ± 0.7 Ma and subsequent metamorphism at 55.1 ± 1.3 and 41.4 ± 2.3 Ma. Our results suggest that the late Cretaceous magmatism in the southern Lhasa terrane resulted from Neo-Tethys oceanic slab subduction and we infer that Paleocene crustal anatexis and metamorphism were related to the thermal perturbation caused by rollback of the northward subducted Neo-Tethyan oceanic slab.     

喜马拉雅东构造结——南迦巴瓦构造及组构运动学

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.     

Kinematics and dynamics of the Namche Barwa Syntaxis, eastern Himalaya: Constraints from deformation, fabrics and geochronology

Field observations, deformation and fabric analyses, and precise age data acquired by zircon SHRIMP, LA-ICP-MS U-Pb and ⁴⁰Ar-³⁹Ar dating methods have yielded new constraints on the kinematics and dynamics of the Namche Barwa Syntaxis (NBS) which is the eastern corner of the Himalaya. A two-stage model has been established to explain the formation and evolution of the NBS. The northward indentation of the Indian plate beneath the Lhasa terrane began at 55-40 Ma, and crustal materials at this corner were subducted to depths > 70 km where they experienced HP (UHP?) metamorphism. Since 40 Ma, large-scale, right-lateral strike-slip along the Sagaing fault has accommodated the rapid northward movement of the eastern Indian plate corner with respect to the Indochina block. This caused significant and progressive bending of the Indus-Yarlung suture zone (IYSZ) such that it became the Dongjiu-Milin left-lateral, strike-slip, shear zone (DMSZ) in the west and the Aniqiao-Motuo right-lateral, strike-slip, shear zone (AMSZ) in the east. Both zones underwent strong mylonitization. Meanwhile, the HP (UHP?) metamorphic rocks were rapidly exhumed, first into the deep crust at 22-18 Ma and then to the shallow crust to form an antiformal dome at 6-2 Ma. Our model provides new insight into the processes of post-collisional crustal thickening related to the formation of the Himalayan orogenic belt.