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1.
位于青藏高原南部的冈底斯岩浆弧形成于中生代新特提斯大洋岩石圈的长期俯冲过程中,而且在印度与亚洲大陆碰撞过程中叠加了强烈的新生代岩浆作用,是世界上典型的复合型大陆岩浆弧,已经成为研究汇聚板块边缘岩浆作用和大陆地壳生长与再造的天然实验室。基于对现有研究成果的总结,我们将冈底斯岩浆弧的岩浆构造演化划分为5个阶段:第1阶段发生在晚白垩世之前,以新特提斯洋岩石圈长期正常俯冲和钙碱性弧岩浆岩的发育为特征;第2阶段发生在晚白垩世时期,以活动的新特提斯洋中脊发生俯冲和强烈的岩浆作用与显著的新生地壳生长为特征;第3阶段发生在晚白垩世晚期,以残余的新特提斯大洋岩石圈俯冲和正常弧型岩浆作用为特征;第4阶段发生在古新世至中始新世,以印度与亚洲大陆碰撞、俯冲的新特提斯洋岩石圈回转和断离,及其诱发的幔源岩浆作用、新生和古老地壳的强烈再造为特征;第5阶段为发生在晚渐新世到中中新世的后碰撞阶段,深俯冲印度岩石圈的回转和断离,或加厚岩石圈地幔的对流移去导致了加厚下地壳的部分熔融和埃达克质岩石的广泛发育,同时伴随幔源钾质超钾质岩浆作用。冈底斯弧岩浆作用与岩浆成分的系统时空变化很好地记录了从新特提斯洋俯冲到印度亚洲大陆碰撞的完整构造演化过程。 相似文献
2.
大陆地壳如何形成是国际学术界长期关注并正在持续攻关的一个重大基础科学问题。活动陆缘弧的岩浆成因和密度分选过程是理解大陆地壳形成机制和演化过程的关键。北美白垩纪Cordilleran大陆边缘弧的形成可能经历了与底侵幔源岩浆有关的下地壳部分熔融和岩浆混合,或幔源初始玄武质岩浆的两阶段成分分异过程,以花岗质成分为主的北美内华达地区垂向地壳成分剖面结构可能与榴辉岩相残留体或堆晶岩的拆沉作用密切相关。目前并不清楚亚洲大陆南部以约200 Ma和约90 Ma两个时间断面为代表的中生代冈底斯弧,为何出现大量角闪石岩并具有玄武安山质的平均成分。探究中生代冈底斯弧的岩浆成因、地壳垂向成分结构和地壳形成机制可能有助于或多或少地解决这一问题。 相似文献
3.
西藏冈底斯东段墨竹工卡地区洞中拉辉绿玢岩锆石SHRIMP U-Pb定年及意义 总被引:2,自引:0,他引:2
洞中拉地区的辉绿玢岩出露于冈底斯弧背断隆带东段,地质研究程度很低,过去一直认为形成于古生代二叠纪。为精确地限制洞中拉辉绿玢岩的形成时代,对冈底斯东段墨竹工卡县洞中拉地区的辉绿玢岩进行锆石SHRIMP U-Pb定年,结果显示洞中拉辉绿玢岩的年龄为117.1Ma±1.0Ma,为早白垩世中期。与冈底斯带中北部地区带状岩浆大爆发的年龄(大约110Ma)时限和冈底斯弧后裂谷拉张作用的时限(120~95Ma)相一致。洞中拉辉绿玢岩可能是冈底斯弧背断隆东段早白垩世弧间裂谷阶段岩浆侵位的产物,与班公湖-怒江特提斯洋壳向南、新特提斯洋壳向北的双向俯冲有关。 相似文献
4.
青藏高原东缘构造演化的SHRIMP锆石U-Pb年代学框架 总被引:6,自引:2,他引:4
青藏高原东缘一直被普遍认为是一个吸收印度—欧亚大陆碰撞变形的调节带。本文所获得的最新SHRIMP锆石U-Pb测年结果显示:青藏高原东缘具有更加复杂的地质历史。测年结果表明,高原东缘最古老的前寒武纪结晶基底形成于古元古代(2401~1912Ma)。这一古老基底首先受到中元古代构造热事件(1361~1040Ma)的影响,随后受到新元古代与弧岩浆活动有关构造热事件(791~817Ma)的强烈改造。松潘—甘孜复理石杂岩的基底是亲洋壳型的,形成于晚新元古代的大陆裂解作用(681~655Ma)。高原东缘的前寒武纪微地块可能是由这次裂解作用从扬子或青藏地块拉裂出去形成的。这些微陆块先增生拼贴于东冈瓦纳大陆、然后又从中裂离,并最终卷入高原东缘的特提斯构造演化过程中。伴随东冈瓦纳大陆裂解,高原东缘古特提斯洋于石炭纪至二叠纪早期拉开(328~292Ma),经早中生代弧-陆碰撞作用闭合(224~213Ma)。中侏罗世这一地区发育显著的构造岩浆活动(175Ma),但其动力学背景仍不十分清楚。晚白垩世岩浆活动(97Ma)可能是印度板块初始俯冲阶段的产物。新生代岩浆作用(18Ma)与陆-陆碰导致的大规模走滑断层作用所引起的同熔作用有关。 相似文献
5.
义敦岛弧是喜马拉雅巨型造山带中的一个复合造山带,它经历了印支期洋壳俯冲造山、燕山湖弧-陆碰撞和喜马拉雅期陆内走滑作用诸演化历史。可能由于洋壳板片俯冲角度不同,义敦晚三叠世古岛弧带(206~237 Ma)南北两段具有不同的发育历史,北段昌台弧以发育孤间裂谷为特色,具张性弧特征,发育扩张环境流体聚敛成矿系统,形成VMS型Zn-Pb-Cu矿床和浅成低温热液型Ag-Au-Hg矿床;南段中甸弧不发育弧后盆地,但广泛发育钙碱性弧火山岩-玢岩-斑岩杂岩系和挤压环境岩浆-流体成矿系统,形成斑岩型-夕卡岩型铜多金属矿床。在三叠纪-侏罗纪之交的弧-陆碰撞作用中,早期大陆板片俯冲形成同碰撞花岗岩带(约200 Ma),晚期造山后伸展作用,形成A型花岗岩带(75~138 Ma),伴随扬子大陆板片俯冲而发生的强烈剪切和推覆,在甘孜-理塘蛇绿混杂带发育挤压剪切环境流体聚敛成矿系统,形成剪切带型金矿。伴随造山后伸展和A型花岗岩侵位,发育伸张环境岩浆-流体聚敛成矿系统,主要形成夕卡岩型锡矿和构造破碎带热浪脉型银多金属矿床。印度-亚洲大陆碰撞在义敦造山带主要表现为陆内走滑作用,并控制碱性花岗岩和花岗斑岩的发育(50~30 Ma),伴随斑岩型金矿的形成。 相似文献
6.
冈底斯岩浆弧的形成与演化 总被引:10,自引:6,他引:4
位于青藏高原南部的冈底斯岩浆弧是新特提斯大洋岩石圈长期俯冲导致的中生代岩浆作用的产物,而且在印度与亚洲大陆碰撞过程中叠加了强烈的新生代岩浆作用,是世界上典型的复合型大陆岩浆弧,也是研究增生与碰撞造山作用和大陆地壳生长与再造的天然实验室。基于岩浆、变质和成矿作用研究成果,我们将冈底斯弧的形成与演化历史划分5期,即新特提斯洋早期俯冲、新特提斯洋中脊俯冲、新特提斯洋晚期俯冲、印度-亚洲大陆碰撞和后碰撞期。第1期发生在晚白垩世之前,是以新特提斯洋岩石圈的长期俯冲、地幔楔部分熔融形成钙碱性弧岩浆岩为特征。长期的幔源岩浆作用导致了整个冈底斯弧发生显著的新生地壳生长,并在岩浆弧西部形成了一个大型的与俯冲相关的斑岩型铜矿。第2期发生在晚白垩世,活动的新特提斯洋中脊发生俯冲,软流软圈沿板片窗上涌,使上升的软流圈、地幔楔和俯冲洋壳发生部分熔融,导致了强烈的幔源岩浆作用和显著的新生地壳生长与加厚,并以不同类型和不同成分岩浆岩的同时发育和伴随的高温变质作用为特征。第3期发生在晚白垩世晚期,为新特提斯洋脊俯冲后残余大洋岩石圈的俯冲期,以正常的弧型岩浆作用为特征。第4期发生在古新世至中始新世,伴随印度与亚洲大陆的碰撞,俯冲的新特提斯洋岩石圈回转和断离引起软流圈上涌,诱发了强烈的幔源岩浆作用。在此阶段,大陆碰撞导致的地壳挤压缩短和幔源岩浆的底侵与增生,使冈底斯弧经历了显著的地壳生长和加厚,新生和古老加厚下地壳的高压、高温变质和部分熔融,幔源和壳源岩浆岩的共生和强烈的岩浆混合。所形成的I型花岗岩大多继承了新生地壳弧型岩浆岩的化学成分,并多显出埃达克岩的地球化学特征。在岩浆弧北部形成了一系列与起源于古老地壳花岗岩相关的Pb-Zn矿床。第5期发生在晚渐新世到早-中中新世的后碰撞挤压过程中,以地壳的继续加厚,加厚下地壳的高温变质、部分熔融和埃达克质岩石的形成为特征。在岩浆弧东段南部形成了一系列与起源于新生加厚下地壳埃达克质岩石相关的斑岩型Cu-Au-Mo矿。冈底斯带的多期岩浆、变质与成矿作用为其从新特提斯洋俯冲到印度-亚洲大陆碰撞的构造演化提供了重要限定。 相似文献
7.
西藏冈底斯地块中新生代中酸性侵入岩浆活动与构造演化 总被引:4,自引:0,他引:4
冈底斯地块上的中新生代中酸性岩浆活动,是北部班公湖-怒江和南部雅鲁藏布两个特提斯演化及其后的陆内汇聚碰撞造山和后造山伸展等大地构造事件的完整记录.地块上的中酸性岩浆活动可划分为3个带,其中北部岩带岩浆岩形成于燕山期,其类型从早期的Ⅰ型到中期的过渡型演化为晚期的S型,分别形成于板块俯冲-缝合-碰撞等构造条件下,是北部班公湖-怒江特提斯演化的集中反映.中部和南部岩浆岩带则集中体现了雅鲁藏布特提斯时空演化的完整经历.其中,南部岩带岩体以燕山晚期为主,喜马拉雅早期次之,成因及形成环境与特提斯洋壳向北俯冲作用密切相关(燕山晚期),同时俯冲结束后的同碰撞条件下的岩浆活动在该岩带内也有明显的反映(喜马拉雅早期);中部岩带岩体以喜马拉雅早期为主,燕山晚期次之.岩体大部分为同碰撞环境下岩浆活动的产物,它表征了随着洋壳板块向北俯冲程度的加深和强度的加剧,岩浆活动中心在不断向北迁移,并最终缝合碰撞的过程.因此该岩带内岩浆岩主要形成于俯冲的晚阶段及缝合后的同碰撞条件下.喜马拉雅晚期的小斑岩体实际上广泛出露于整个冈底斯地块上,它反映的是该区在经历了碰撞造山后发生的陆内伸展的构造过程. 相似文献
8.
本文通过对西昆仑西段地区晚古生代—中生代花岗岩的岩石类型、形成时代和岩石地球化学资料的综合分析,探讨花岗质岩浆活动期次、岩石成因,结合区域资料,探讨构造-岩浆演化特征和碰撞造山过程。将该地区晚古生代—中生代构造-岩浆演化分为7个阶段:(1)388~324 Ma(特提斯Ⅰ、Ⅱ支洋向北俯冲消减阶段),具富钠贫钾特征的低温TTG岩石组合,形成于陆缘弧环境;(2)339~291 Ma(奥依塔格弧后盆地演化阶段),由于南部特提斯Ⅰ支洋持续往北俯冲,导致西昆仑北缘发生弧后扩展而形成弧后盆地,形成拉斑质具强烈富钠贫钾特征的低温大洋花岗岩;(3)258~241 Ma(特提斯Ⅰ支洋闭合、碰撞造山阶段),岩石中发育石榴子石和白云母,普遍具片麻状构造,属于S型花岗岩,陆壳部分熔融的产物;(4)234~210 Ma(特提斯Ⅰ后碰撞伸展阶段):岩体规模较大,为I型→A型花岗岩,伴随着地幔岩浆底侵和强烈的壳幔岩浆混合作用;(5)198~150 Ma(特提斯Ⅱ支洋向南俯冲消减阶段):类似TTG的岩石组合,形成于与洋壳俯冲有关的岩浆弧环境;(6)148~118 Ma(特提斯Ⅱ支洋闭合、碰撞造山阶段):弱片麻状二云二长花岗岩,属C型埃达克岩,为陆-陆碰撞过程中陆壳加厚发生部分熔融的产物;(7)111~75 Ma(特提斯Ⅱ后碰撞伸展阶段):发育规模较大,钾玄质系列,是古老地壳部分熔融的产物。根据各阶段花岗质岩浆活动特征和构造演化过程,初步提出了西昆仑西段晚古生代—中生代大地构造演化模式图。 相似文献
9.
碰撞带前陆盆地的建立是大陆碰撞的直接标志和随后造山带构造变形的忠实记录。本文对欧亚板块与印度板块碰撞前后发育在拉萨地块上的冈底斯弧背前陆盆地,同碰撞产生的雅鲁藏布江周缘前陆盆地,以及碰撞后陆内变形产生的喜马拉雅前陆盆地的沉积地层演化以及碎屑锆石物源特征等进行了系统分析,结合前人及我们近些年的研究成果,认为冈底斯岛弧北侧发育一个典型的弧背前陆盆地系统而不是以前普遍接受的伸展盆地。除传统认为的喜马拉雅前陆盆地系统外,在碰撞造山带中还发育一个雅鲁藏布江前陆盆地系统,它是欧亚板块与印度板块碰撞以后,欧亚板块加载到印度被动大陆边缘产生的典型周缘前陆盆地。上述2个造山带前陆盆地系统的识别,大大提高了对新特提斯洋俯冲、碰撞过程的认识。造山带前陆盆地证据指示,新特提斯洋至少于140 Ma以前就已开始俯冲, 110 Ma俯冲速度开始提高,在65 Ma前后印度大陆与欧亚大陆发生碰撞,喜马拉雅山于40 Ma开始隆升,其剥蚀物质大量堆积在喜马拉雅前陆盆地中。 相似文献
10.
青藏高原碰撞造山带:Ⅲ. 后碰撞伸展成矿作用 总被引:97,自引:20,他引:97
“后碰撞”作为大陆碰撞造山作用的特定过程,以其重要的构造演化标示性特征和强烈的爆发式金属成矿作用,受到人们的高度重视。但涉及后碰撞的一系列重要地质问题,如后碰撞期的构造特征与演化历程、岩浆发育序列和岩石构造组合、伸展成矿作用与矿床系列组合等,尚未得到清楚完好的识别、理解和阐示。文章系统研究和总结了青藏高原后碰撞造山与成矿作用特征,提出了后碰撞伸展成矿作用的构造控制模型。研究表明,现今处于后碰撞阶段的青藏高原,中新世以来主要经历了两阶段发育历史。后碰撞早期阶段主要发生下地壳流动与上地壳缩短(>18Ma):下地壳塑性流动并向南挤出,在藏南地区形成EW向延伸的藏南拆离系(STD)和高喜马拉雅,上地壳强烈逆冲推覆,在拉萨地体发育EW向展布的逆冲断裂系;晚期阶段主要发生地壳伸展与裂陷(<18Ma):垂直碰撞带的EW向伸展,形成一系列横切青藏高原的NS向正断层系统(≤13·5Ma)及其围陷的裂谷系和裂陷盆地。后碰撞岩浆作用以形成钾质_超钾质火山岩、钾质埃达克岩、钾质钙碱性花岗岩与淡色花岗岩为特征,集中发育于冈底斯构造_岩浆带和藏南特提斯喜马拉雅。淡色花岗岩与藏南拆离构造有关,其他钾质_超钾质岩浆活动则与EW向地壳伸展有关。青藏高原后碰撞成矿作用强烈而复杂,主要形成斑岩型Cu矿、热液脉型Sb_Au矿、矽卡岩型和热液脉型Ag_Pb_Zn矿以及现代热泉型Cs_Au矿等重要矿床类型。斑岩型Cu矿及矽卡岩型多金属矿床形成于后碰撞伸展环境,岩浆起源于加厚的镁铁质新生下地壳;热液脉型Sb_Au矿发育于藏南拆离带及变质核杂岩周围,系中新世地热田浅成低温热液活动产物。热液脉型Ag_Pb_Zn矿主要产于拉萨地体内部的逆冲构造带内,与地壳流体的迁移汇聚过程有关。青藏高原后碰撞成矿作用在上地壳层次受3大构造系统控制,即①东西向伸展形成的近NS向正断层系统及裂谷裂陷带,②南北向地壳缩短形成的EW向展布的逆冲构造带和③EW向展布的拆离构造带,但在中下地壳/地幔层次上,则受中下地壳物质流动_挤出过程以及俯冲大陆板片断离_拆沉过程控制。 相似文献
11.
《地学前缘(英文版)》2020,11(3):895-914
A section from the Linglong gold deposit on the northwestern Jiaodong Peninsula,East China,containing Late Mesozoic magmatic rocks from mafic and intermediate dikes and felsic intrusions,was chosen to investigate the lithospheric evolution of the eastern North China Craton(NCC).Zircon U-Pb data showed that low-Mg adakitic monzogranites and granodiorite intrusions were emplaced during the Late Jurassic(~145 Ma) and late Early Cretaceous(112-107 Ma),respectively;high-Mg adakitic diorite and mafic dikes were also emplaced during the Early Cretaceous at~139 Ma and ~118 Ma,and 125-145 Ma and 115-120 Ma,respectively.The geochemical data,including whole-rock major and trace element compositions and Sr-Nd-Pb isotopes,imply that the mafic dikes originated from the partial melting of a lithospheric mantle metasomatised through hydrous fluids from a subducted oceanic slab.Low-Mg adakitic monzogranites and granodiorite intrusions originated from the partial melting of the thickened lower crust of the NCC,while high-Mg adakitic diorite dikes originated from the mixing of mafic and felsic melts.Late Mesozoic magmatism showed that lithosphere-derived melts showed a similar source depth and that crust-derived felsic melts originated from the continuously thickened lower crust of the Jiaodong Peninsula from the Late Jurassic to Early Cretaceous.We infer that the lower crust of the eastern NCC was thickened through compression and subduction of the Palaeo-Pacific plate beneath the NCC during the Middle Jurassic.Slab rollback of the plate from ~160 Ma resulted in lithospheric thinning and accompanied Late Mesozoic magmatism. 相似文献
12.
藏南林周盆地设兴组砂岩及其中玄武岩夹层的地球化学与成因 总被引:1,自引:1,他引:0
印度与亚洲大陆的碰撞是青藏高原演化的重要构造事件,碰撞过程被记录在拉萨地块南部的晚白垩世到古新世的沉积-岩浆作用中。林周盆地的晚白垩世设兴组及其之后不整合覆盖的林子宗火山岩,是解析碰撞过程的重要记录。本文对设兴组最高层位的砂岩和玄武岩夹层进行了岩石学、地球化学和年代学研究,探讨了岩石成因和构造意义。设兴组砂岩属于杂砂岩,碎屑物质主要来自中酸性岩浆岩源区;锆石Hf同位素指示设兴组大部分碎屑物质来源于盆地北面的中部拉萨地块,少部分来自盆地南部的冈底斯岩基;砂岩中最年轻的碎屑锆石年龄指示林周盆地设兴组是在98Ma之后接受沉积的。以夹层产出在设兴组顶部的玄武岩和玄武安山岩,富集轻稀土元素、亏损重稀土元素、弱负Eu异常,强烈富集Ba、Th、U、Pb等大离子亲石元素,显著亏损Nb、Ta等高场强元素,属于高钾钙碱性玄武岩系列,与典型安第斯型玄武岩特征吻合。玄武岩和玄武安山岩的锆石均为捕获锆石,其最年轻碎屑锆石年龄限定了设兴组玄武岩的喷发晚于110Ma。综合分析表明,林周盆地晚白垩世时期为夹持在冈底斯岩浆弧与中部拉萨地块之间的弧后盆地,新特提斯洋壳晚白垩世俯冲到冈底斯弧和弧后盆地之下,大约在98~110Ma之后喷发到林周盆地的很少量中基性岩浆构成了设兴组顶部的玄武岩和玄武安山岩夹层,是新特提斯洋俯冲相关的幔源岩浆作用。林周盆地设兴组(晚于98Ma)与上覆的林子宗火山岩(底部约为65Ma)之间呈大约33Myr的构造间断,可能代表了冈底斯弧的碰撞之前的隆升剥蚀过程。 相似文献
13.
《China Geology》2021,4(1):56-66
The timing of the initial Indo-Asian collision is a subject of debate for a long time. Besides, the magmatic trace of the collisional process is also unclear. In the present study, the authors report Early Eocene leucocratic sill/dike swarms in the northern edge of the Nymo intrusive complex of the Gangdese belt, southern Tibet. The Nymo intrusive complex was emplaced at ca. 50 –47 Ma and surrounded by the metamorphosed Jurassic-aged Bima Formation volcano-sedimentary sequence along its northern side. At outcrops, the leucocratic sills/dikes intruded along or truncated the deformed foliations of the host Bima Formation, which has been subject to high-temperature amphibolite-facies metamorphism at ca. 50 –47 Ma. Detailed cathodoluminescence image analyses reveal that the zircon grains of the leucocratic sills/dikes have core-mantle textures. The cores yield the Jurassic ages comparable to the protolith ages of the Bima Formation. In contrast, the mantles of zircon grains yield weighted mean ages of ca. 49–47 Ma, representing the crystallization timing of these leucocratic sills/dikes. The coeval ages for the Nymo intrusive complex, the high-temperature metamorphism, and the leucocratic sills/dikes indicate that a close relationship exists among them. The authors tentatively suggest that these leucocratic sills/dikes were generated from partial melting of the Jurassic-aged Bima Formation volcanic rocks, triggered by the high heat from the magma chamber of the Nymo intrusive complex. This Early Eocene tectono-thermal event of coeval magmatism, metamorphism and partial melting was most likely formed during the Indo-Asian collisional setting.©2021 China Geology Editorial Office. 相似文献
14.
Christian Creixell Miguel Ángel Parada Diego Morata Pierrick Roperch César Arriagada 《International Journal of Earth Sciences》2009,98(1):177-201
Five mafic dike swarms between 30° and 33°45′S were studied for their geochemical signature and kinematics of magma flow directions
by means of AMS data. In the Coastal Range of central Chile (33°−33°45′S), Middle Jurassic dike swarms (Concón and Cartagena
dike swarms, CMDS and CrMDS, respectively) and an Early Cretaceous dike swarm (El Tabo Dike Swarm, ETDS) display the presence
of dikes of geochemically enriched (high-Ti) and depleted (low-Ti) basaltic composition. These dikes show geochemical patterns
that are different from the composition of mafic enclaves of the Middle Jurassic Papudo-Quintero Complex, and this suggests
that the dikes were injected from reservoirs not related to the plutonic complex. The mantle source appears to be a depleted
mantle for Jurassic dikes and a heterogeneous-enriched lithospheric mantle for Cretaceous dikes. In the ETDS, vertical and
gently plunging magma flow vectors were estimated for enriched and depleted dikes, respectively, which suggest, together with
variations in dike thickness, that reservoirs were located at different depths for each dike family. In the Elqui Dike Swarm
(EDS) and Limarí Mafic Dike Swarm (LMDS), geochemical patterns are similar to those of the mafic enclaves of the Middle Jurassic
plutons. In the LMDS, east to west magma flow vectors are coherent with injection from neighbouring pluton located to the
east. In the EDS, some dikes show geochemical and magma flow patterns supporting the same hypothesis. Accordingly, dikes do
not necessarily come from deep reservoir; they may propagate in the upper crust from coeval shallow pluton chamber.
Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. 相似文献
15.
16.
西藏安多地区早古生代及中生代造山记录:来自安多微陆块-南羌塘锆石U-Pb年代学及Hf同位素研究 总被引:1,自引:1,他引:0
安多地区位于青藏高原腹地,为拉萨地体、羌塘地体及安多微陆块的结合部位,是研究拉萨地体、羌塘地体起源以及特提斯造山过程的关键位置。我们对采自安多地区的前中生代基底岩石及侏罗系沉积岩样品进行了岩石学、锆石U-Pb年代学及Hf同位素研究。研究结果表明:安多花岗片麻岩中锆石同时记录了510~505Ma岩浆年龄以及187Ma变质年龄;187Ma的变质锆石与510~505Ma的岩浆锆石具有相似的Hf同位素模式年龄(1.7~1.5Ga),表明寒武纪花岗岩主要来源于古老地壳重熔。碎屑锆石年代学分析结果揭示了安多微陆块石英岩具有498~484Ma、800~1000Ma和1800~1950Ma的年龄峰值,与南羌塘地体及特提斯喜马拉雅碎屑锆石年龄分布特征相似,表明其在早古生代时位于冈瓦纳大陆北部印度陆块边缘。南羌塘坳陷东南部中侏罗世砂岩及钙质砂岩碎屑锆石年代学分析结果显示其具有182~171Ma、450~600Ma、800~1000Ma、1800~1950Ma及2400~2600Ma的年龄峰值,这种年龄分布特征与安多微陆块及南羌塘地体相似,而与拉萨地体不同,说明南羌塘坳陷东南部下-中侏罗统物源主要来自安多微陆块及南羌塘地体,在早-中侏罗世时安多微陆块与南羌塘地体已经发生了碰撞造山。 相似文献
17.
High-precision 40Ar/39Ar dating of lamprophyre dike swarms in the Western Province of New Zealand reveals that these dikes were emplaced into continental crust prior to, during and after opening of the Tasman Sea between Australia and New Zealand. Dike ages form distinct clusters concentrated in different areas. The oldest magmatism, 102–100 Ma, is concentrated in the South Westland region that represents the furthest inboard portion of New Zealand in a Gondwana setting. A later pulse of magmatism from ~ 92 Ma to ~ 84 Ma, concentrated in North Westland, ended when the first oceanic crust formed at the inception of opening of the Tasman Sea. Magmatic quiescence followed until ~ 72–68 Ma, when another swarm of dikes was emplaced. The composition of the dikes reveals a dramatic change in primary melt sources while continental extension and lithospheric thinning were ongoing. The 102–100 Ma South Westland dikes represent the last mafic calc-alkaline magmatism associated with a long-lived history of the area as Gondwana's active margin. The 92–84 Ma North and 72–68 Ma Central Westland dike swarms on the other hand have strongly alkaline compositions interpreted as melts from an intraplate source. These dikes represent the oldest Western Province representatives of alkaline magmatism in the greater New Zealand region that peaked in activity during the Cenozoic and has remained active up to the present day. Cretaceous alkaline dikes were emplaced parallel to predicted normal faults associated with dextral shear along the Alpine Fault. Furthermore, they temporally correspond to polyphase Cretaceous metamorphism of the once distal Alpine Schist. Dike emplacement and distal metamorphism could have been linked by a precursor to the Alpine Fault. Dike emplacement in the Western Province coupled to metamorphism of the Alpine Schist at 72–68 Ma indicates a period of possible reactivation of this proto Alpine Fault before it served as a zone of weakness during the opening of the oceanic Emerald Basin (at ~ 45 Ma) and eventually the formation of the present-day plate boundary (~ 25 Ma–recent). 相似文献
18.
The Neo‐Tethyan subduction that operated before the India‐Asia collision resulted in an Andean‐type convergent margin in South Asia and was associated with extensive arc magmatism that formed the Transhimalayan batholiths. Magmatism in the Gangdese Batholith, the largest batholith exposed in the Lhasa terrane of southern Tibet, is considered to have lasted from the early Jurassic to Eocene. However, eastward correlation of the Gangdese Batholith is uncertain because it is truncated by the eastern Himalayan syntaxis. Here, we report new data from the Lohit Batholith, NE India, including: (i) zircon U‐Pb ages of five granitoids from ca. 148 to 96 Ma; and (ii) zircon Hf isotopes of these rocks that yield high and positive εHf(T) values. We argue that the Lohit Batholith is the eastward extension of the Gangdese Batholith, and can be correlated southward to the Wuntho‐Popa arc in West Burma, thus linking a prolonged Neo‐Tethyan magmatic arc system from southern Tibet to Southeast Asia. 相似文献
19.
Cenozoic volcanism on the Tibetan plateau, which shows systematic variations in space and time, is the volcanic response to the India–Asia continental collision. The volcanism gradually changed from Na-rich + K-rich to potassic–ultrapotassic + adakitic compositions along with the India–Asia collision shifting from contact-collision (i.e. “soft collision” or “syn-collision”) to all-sided collision (i.e. “hard collision”). The sodium-rich and potasium-rich lavas with ages of 65–40 Ma distribute mainly in the Lhasa terrane of southern Tibet and subordinately in the Qiangtang terrane of central Tibet. The widespread potassic–ultrapotassic lavas and subordinate adakites were generated from ~ 45 to 26 Ma in the Qiangtang terrane of central Tibet. Subsequent post-collisional volcanism migrated southwards, producing ultrapotassic and adakitic lavas coevally between ~ 26 and 8 Ma in the Lhasa terrane. Then potassic and minor adakitic volcanism was renewed to the north and has become extensive and semicontinuous since ~ 20 Ma in the western Qiangtang and Songpan–Ganze terranes. Such spatial–temporal variations provide important constraints on the geodynamic processes that evolved at depth to form the Tibetan plateau. These processes involve roll-back and break-off of the subducted Neo-Tethyan slab followed by removal of the thickened Lhasa lithospheric root, and consequently northward underthrusting of the Indian lithosphere. The Tibetan plateau is suggested to have risen diachronously from south to north. Whereas the southern part of the plateau may have been created and maintained since the late-Oligocene, the northern plateau would have not attained its present-day elevation and size until the mid-Miocene when the lower part of the western Qiangtang and Songpan–Ganze lithospheres began to founder and detach owing to the persistently northward push of the underthrust Indian lithosphere. 相似文献
20.
改则地区的嘎布扎花岗闪长岩侵入于南羌塘地体南缘的侏罗系色哇组,为研究班公湖—怒江缝合带的演化提供新的约束。岩浆锆石的LA-ICP-MS U-Pb年龄为(143.8±0.5)Ma,显示花岗闪长岩的侵位时代为晚侏罗世—早白垩世之交。花岗闪长岩具有准铝质I型花岗岩的特点,属于高钾钙碱性岩石系列;稀土元素为轻稀土富集型,存在弱的Eu负异常;明显富集Rb、Ba、K、Th、U等大离子亲石元素,而亏损Nb、Ta、P、Ti等高场强元素。研究表明花岗闪长岩的岩浆源区可能经历了陆壳物质、俯冲沉积物与幔源楔等不同性质的岩浆混合,并经历一定程度的分离结晶作用形成。改则嘎布扎花岗闪长岩形成于班公湖—怒江中特提斯洋晚侏罗世—早白垩世向北俯冲的岛弧环境。 相似文献