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1.
在西藏1∶25万喀纳幅、日土县幅地质调查图成果的基础上,重建了班公湖-怒江结合带西段3个地层区的侏罗纪-早白垩世沉积地层序列,对地层纵向、横向序列变化和沉积环境进行对比分析,指出在侏罗纪-早白垩世时,班公湖-怒江中特提斯洋盆沉积与其南、北两侧大陆边缘沉积有明显差异;中特提斯海洋盆地演化经历了早-中侏罗世深海-半深海沉积、晚侏罗世-早白垩世残余海(洋)盆地沉积和晚白垩世残余海盆消亡等3个阶段。  相似文献   

2.
应用地层对比、砂岩岩相学和碎屑锆石U-Pb年代学的方法,重建东巧—北拉地区物源转换和班公湖—怒江洋多期次俯冲及微陆块的拼合过程。研究表明:东卡错微陆块南侧的中下侏罗统希湖群下段表现为上三叠统确哈拉群的再旋回沉积,而北侧上段则开始出现来自羌塘地区的物质。这标志着北侧早侏罗世俯冲的东巧分支洋盆消亡,东卡错微陆块在中侏罗世与羌塘地块拼合开始形成初始周缘前陆盆地。接奴群的物源完全来自南羌塘地区,表明周缘前陆盆地在微陆块南侧北拉洋俯冲挤压下持续发育。晚侏罗世—早白垩世(147~141 Ma)拉萨地块和羌塘地块东西向全面碰撞,至早白垩世晚期(约120 Ma)南侧的分支洋盆北拉洋消亡代表碰撞结束。南羌塘地区受班公湖—怒江洋俯冲作用控制在早侏罗世发育由弧前—岩浆弧—弧后盆地组成的“一隆两坳”古地貌,并沉积了曲色组页岩和布曲组石灰岩。微陆块碰撞导致南羌塘盆地的隆起和海平面的下降,形成夏里组含膏质泥岩的潮坪相沉积。随着拉萨地块和羌塘地块的全面碰撞,南羌塘盆地从弧相关盆地卷入前陆盆地褶皱冲断带中,发生差异埋藏和隆升剥蚀。晚侏罗世—早白垩世,南羌塘盆地曲色组烃源岩和布曲组石灰岩在构造挤压作用下发生快速埋藏,进...  相似文献   

3.
笔者依据班公湖地区1:25万喀纳幅、日土县幅、羌多幅地质填图和专题研究工作取得的阶段性成果,将班公湖带的多岛弧盆系时空结构厘定为3条蛇绿混杂岩亚带。该3条亚带为盆地所隔,从北而南依次为班公湖带北亚带、班摩掌侏罗纪弧间盆地、班公湖带中亚带、日土-巴尔穷侏罗纪—早白垩世复合弧后盆地和班公湖带南亚带等。初步认为班公湖-怒江特提斯洋经历了晚三叠—早侏罗世往北俯冲、中晚侏罗世早期向北、往南双向俯冲、早白垩世往南俯冲等3次俯冲消亡阶段;同时,讨论了在班公湖带研究中存在的问题及其在反演班公湖-怒江结合带西段构造演化和在找矿方面的意义,以及进一步研究方向。  相似文献   

4.
青藏高原中部狮泉河-拉果错-永珠-嘉黎蛇绿混杂岩带(简称SYMZ)位于班公湖-怒江缝合带与雅鲁藏布江缝合带之间,其构造属性存在很大争议,制约了对青藏高原多岛弧盆系构造演化的理解.根据新的地质调查资料、研究成果并结合分析数据,系统总结了该蛇绿混杂岩带的地质特征,讨论了其构造演化过程.一系列新资料及新认识表明SYMZ是分割北拉萨地块和中拉萨地块的一条独立的蛇绿混杂岩带,是特提斯构造域多岛弧盆系的组成部分.在狮泉河、拉果错、阿索、永珠、凯蒙等地发育比较典型的蛇绿岩组合,高精度年代学数据指示洋盆主体发育于178~160 Ma,比班公湖-怒江洋盆主体发育时限(188~162 Ma)要晚10 Ma左右,阿索一带蛇绿岩残片记录洋盆一直持续到113 Ma.SYMZ侏罗纪基性岩具有MORB型(洋中脊玄武岩)和IAT型(岛弧拉斑玄武岩)火山岩的地球化学性质,属于洋内弧型和洋中脊型蛇绿混杂岩;早白垩世基性岩具MORB和火山弧玄武岩的双重特性,指示其很可能形成于SSZ的构造环境,不同于同时期班公湖-怒江特提斯受地幔柱热点影响的洋盆性质.同时,在拉果错、永珠、凯蒙等地区识别出侏罗纪前弧玻安岩及玻玄岩系列,一致指示SYMZ洋壳发生过洋内俯冲.在此基础上,结合区域地质资料,构建了SYMZ特提斯洋的时空格架及构造演化历史,认为经历了晚三叠世-早侏罗世洋盆裂解-扩张、中-晚侏罗世洋内俯冲、早白垩世俯冲消减和早白垩世末期洋盆消亡四个阶段,为特提斯洋的构造演化及大地构造过程再造提供了重要的地质学证据.   相似文献   

5.
班公湖—怒江结合带南侧弧-盆系时空结构与演化特征   总被引:14,自引:4,他引:14       下载免费PDF全文
本文在1:25万邦多区幅、措麦区幅填图成果基础上,运用多岛弧造山模式分析了班公湖—怒江结合带南侧弧-盆系时空结构与演化特征。认为中晚侏罗世—早白垩世,伴随班公湖—怒江洋向南俯冲消亡,其南侧形成多岛弧—盆系的空间配置格局;早白垩世晚期—晚白垩世,残余海盆沉积、闭合消亡及其随后的碰撞造山,完成了班公湖—怒江带南侧弧-盆系时空演化史。  相似文献   

6.
班公湖-怒江结合带西段中特提斯多岛弧构造演化   总被引:13,自引:0,他引:13       下载免费PDF全文
本文根据1∶25万地质填图成果,将班公湖-怒江结合带西段弧-盆系时空结构自北向南划分为五峰尖-拉热拉新晚侏罗世—早白垩世陆缘火山-岩浆弧带、班公湖蛇绿混杂岩北、南亚带和昂龙岗日-班戈白垩纪—始新世岩浆弧带等,初步认为中特提斯洋经历了三叠纪—早侏罗世扩张,中—晚侏罗世往北、南双向俯冲,晚三叠世—早白垩世残余洋(海)盆和早—晚白垩世陆-弧(陆)碰撞等演化阶段。  相似文献   

7.
本文从构造-岩浆演化、典型矿床特征、构造-岩浆产物空间分布特征等方面,对冈底斯成矿带形成于195~80Ma的与俯冲-碰撞作用相关的斑岩(-矽卡岩)型铜矿的找矿方向进行了探讨。认为研究区与俯冲-碰撞作用相关的斑岩型铜矿大致可分为早-中侏罗世、晚侏罗-早白垩世、晚白垩世3个成矿时期,分别对应于雅鲁藏布江洋向北、班公湖怒江洋向南相向俯冲、班公湖怒江洋碰撞关闭、雅鲁藏布江洋向北持续俯冲、雅鲁藏布江洋向北晚期俯冲等构造-岩浆事件。与早期相向俯冲相关的雄村式矿床,在拉萨东部达孜-工布江达一带具有良好找矿前景;与中期俯冲-碰撞相关的多龙式矿床,在昂龙岗日、东恰错、桑日等火山岩浆弧区成矿条件较佳;与晚期俯冲相关的尕尔穷式矿床,在冈底斯东段和西段具有较大的找矿潜力。  相似文献   

8.
班公湖蛇绿混杂岩带位于班公湖-怒江结合带西段,是中生代特提斯洋消亡的遗迹。根据西藏1∶25万日土县幅、喀纳幅地质填图成果,将班公湖蛇绿混杂岩带的时空结构划分为南、北两条亚带;综合分析研究认为,本区中特提斯洋的演化经历了三叠纪-早中侏罗世扩张,中晚侏罗世双向俯冲,晚侏罗世-早白垩世残余洋(海)盆和晚白垩世陆(弧)-陆碰撞等构造演化阶段。  相似文献   

9.
研究区位于羌塘地块与班公湖—怒江结合带交汇处,保存有一套晚侏罗世—早白垩世海相沉积记录,是研究晚侏罗世—早白垩世班公湖—怒江特提斯洋沉积环境演化及其沉积盆地类型的理想地区。通过对岩性组合、沉积环境、古生物化石等方面进行研究,厘定出欧利组,并探讨了欧利组时代归属及沉积盆地类型。根据欧利组中发现的小光星珊瑚、轮形异通珊瑚、米契林柱剑珊瑚、安多准柱剑珊瑚等化石,确定欧利组时代为晚侏罗世。初步分析沉积环境为局限台地-潮坪沉积,局部具潮汐水道沉积,沉积相分析表明研究区晚侏罗世—早白垩世沉积盆地类型为弧后前陆盆地。  相似文献   

10.
从尼玛地区地质新资料看中特提斯洋的构造演化   总被引:10,自引:0,他引:10       下载免费PDF全文
班公湖—怒江结合带南缘存在一套中、晚侏罗世稳定浅海碎屑岩沉积,属残余海盆地沉积,表明尼玛地区的俯冲消减机制在中侏罗世以后已结束。结合带南侧三叠系确哈拉群为一套半深水—深水沉积,是陆架边缘沉积序列,代表结合带打开之初的较早期沉积。确哈拉群之上不整合覆盖了一套中侏罗世钙碱性岛弧火山岩系,是班公湖—怒江结合带在早侏罗世向南俯冲对应的滞后弧火山岩。在结合带南侧80~100km范围内分布着一条东西长超过100km的中晚侏罗世后碰撞强过铝花岗岩带,属班公湖—怒江结合带向南俯冲碰撞作用的后碰撞阶段产物。综合认为,尼玛地区中特提斯洋是在三叠纪打开、中侏罗世以前向南俯冲闭合的。结合区域上该结合带闭合时间有早有晚、俯冲方向有南有北的事实,提出中特提斯是一个具有众多互不相通的、时代早晚各不相同的小洋盆共同组成的多岛洋,其间存在许多大小不一、运动方向和性质各不相同的地体。不同时期、不同方向的弧—弧碰撞、弧—陆碰撞造山(造陆)机制是解释中特提斯洋发展演化诸多问题的理想模式。  相似文献   

11.
通过1∶5万区域地质调查和收集相关资料的综合研究,本文对雅鲁藏布江结合带的形成演化作了进一步的探讨。雅鲁藏布江特提斯洋具有弧后扩张洋盆的性质,在早三叠世至中三叠世中期洋盆初步形成,中三叠世晚期至晚三叠世洋盆全面形成,从早侏罗世至晚白垩世洋盆逐步萎缩,到古新世至始新世关闭。南带的蛇绿岩主要为洋中脊扩张型(MORB型),形成于中三叠世晚期至晚三叠世。北带的蛇绿岩主要为与洋内俯冲相关的俯冲带上盘型(SSZ型),形成于早中侏罗世。带内侏罗纪至白垩纪其他岩浆岩主要为前弧玄武岩类(FAB型)。显示雅鲁藏布江特提斯洋从早侏罗世开始发生了洋内俯冲,并同步向北向冈底斯带之下主动俯冲消减和向南向喜马拉雅地块之下被动俯冲消减,持续发展到晚白垩世,在古新世至始新世俯冲碰撞消亡转化为结合带。  相似文献   

12.
In this paper, we summarize results of studies on ophiolitic mélanges of the Bangong–Nujiang suture zone (BNSZ) and the Shiquanhe–Yongzhu–Jiali ophiolitic mélange belt (SYJMB) in central Tibet, and use these insights to constrain the nature and evolution of the Neo-Tethys oceanic basin in this region. The BNSZ is characterized by late Permian–Early Cretaceous ophiolitic fragments associated with thick sequences of Middle Triassic–Middle Jurassic flysch sediments. The BNSZ peridotites are similar to residual mantle related to mid-ocean-ridge basalts (MORBs) where the mantle was subsequently modified by interactions with the melt. The mafic rocks exhibit the mixing of various components, and the end-members range from MORB-types to island-arc tholeiites and ocean island basalts. The BNSZ ophiolites probably represent the main oceanic basin of the Neo-Tethys in central Tibet. The SYJMB ophiolitic sequences date from the Late Triassic to the Early Cretaceous, and they are dismembered and in fault contact with pre-Ordovician, Permian, and Jurassic–Early Cretaceous blocks. Geochemical and stratigraphic data are consistent with an origin in a short-lived intra-oceanic back-arc basin. The Neo-Tethys Ocean in central Tibet opened in the late Permian and widened during the Triassic. Southwards subduction started in the Late Triassic in the east and propagated westwards during the Jurassic. A short-lived back-arc basin developed in the middle and western parts of the oceanic basin from the Middle Jurassic to the Early Cretaceous. After the late Early Jurassic, the middle and western parts of the oceanic basin were subducted beneath the Southern Qiangtang terrane, separating the Nierong microcontinent from the Southern Qiangtang terrane. The closing of the Neo-Tethys Basin began in the east during the Early Jurassic and ended in the west during the early Late Cretaceous.  相似文献   

13.
J. Golonka   《Tectonophysics》2004,381(1-4):235
Thirteen time interval maps were constructed, which depict the Triassic to Neogene plate tectonic configuration, paleogeography and general lithofacies of the southern margin of Eurasia. The aim of this paper is to provide an outline of the geodynamic evolution and position of the major tectonic elements of the area within a global framework. The Hercynian Orogeny was completed by the collision of Gondwana and Laurussia, whereas the Tethys Ocean formed the embayment between the Eurasian and Gondwanian branches of Pangea. During Late Triassic–Early Jurassic times, several microplates were sutured to the Eurasian margin, closing the Paleotethys Ocean. A Jurassic–Cretaceous north-dipping subduction boundary was developed along this new continental margin south of the Pontides, Transcaucasus and Iranian plates. The subduction zone trench-pulling effect caused rifting, creating the back-arc basin of the Greater Caucasus–proto South Caspian Sea, which achieved its maximum width during the Late Cretaceous. In the western Tethys, separation of Eurasia from Gondwana resulted in the formation of the Ligurian–Penninic–Pieniny–Magura Ocean (Alpine Tethys) as an extension of Middle Atlantic system and a part of the Pangean breakup tectonic system. During Late Jurassic–Early Cretaceous times, the Outer Carpathian rift developed. The opening of the western Black Sea occurred by rifting and drifting of the western–central Pontides away from the Moesian and Scythian platforms of Eurasia during the Early Cretaceous–Cenomanian. The latest Cretaceous–Paleogene was the time of the closure of the Ligurian–Pieniny Ocean. Adria–Alcapa terranes continued their northward movement during Eocene–Early Miocene times. Their oblique collision with the North European plate led to the development of the accretionary wedge of the Outer Carpathians and its foreland basin. The formation of the West Carpathian thrusts was completed by the Miocene. The thrust front was still propagating eastwards in the eastern Carpathians.During the Late Cretaceous, the Lesser Caucasus, Sanandaj–Sirjan and Makran plates were sutured to the Iranian–Afghanistan plates in the Caucasus–Caspian Sea area. A north-dipping subduction zone jumped during Paleogene to the Scythian–Turan Platform. The Shatski terrane moved northward, closing the Greater Caucasus Basin and opening the eastern Black Sea. The South Caspian underwent reorganization during Oligocene–Neogene times. The southwestern part of the South Caspian Basin was reopened, while the northwestern part was gradually reduced in size. The collision of India and the Lut plate with Eurasia caused the deformation of Central Asia and created a system of NW–SE wrench faults. The remnants of Jurassic–Cretaceous back-arc systems, oceanic and attenuated crust, as well as Tertiary oceanic and attenuated crust were locked between adjacent continental plates and orogenic systems.  相似文献   

14.
中、上扬子北部盆-山系统演化与动力学机制   总被引:5,自引:0,他引:5       下载免费PDF全文
中国南方中生代经历了中国大陆最终主体拼合的陆缘及其之后的陆内构造演化。晚古生代末期,在秦岭—大别山微板块与扬子板块之间存在向西张口的洋盆,即勉略古洋盆。中三叠世末期开始,扬子板块相对于华北板块发生自南东向北西的斜向俯冲碰撞作用,扬子北缘晚三叠世至中侏罗世发育陆缘前陆褶皱逆冲带与前陆盆地系统。晚侏罗世至早白垩世,中国东部的大地构造背景发生了重要的构造转变,中、上扬子地区处于三面围限会聚的大地构造背景。在这种大地构造格局下,中、上扬子地区晚侏罗世至早白垩世发育陆内联合、复合构造与具前渊沉降的克拉通内盆地系统。自中侏罗世末期开始,扬子北缘前陆带与雪峰山—幕阜山褶皱逆冲带经历了自东向西的会聚变形过程及盆地的自东向西的迁移过程和收缩过程。扬子北缘相对华北板块的斜向俯冲导致在中扬子北缘的深俯冲及超高压变质岩的形成。俯冲之后以郯庐断裂—襄广断裂围限的大别山超高压变质地块在晚侏罗世向南强逆冲,致使扬子北缘晚三叠世至中侏罗世前陆盆地被掩覆和改造。  相似文献   

15.
《International Geology Review》2012,54(14):1801-1816
We present new geochronological and geochemical data for granites and volcanic rocks of the Erguna massif, NE China. These data are integrated with previous findings to better constrain the nature of the massif basement and to provide new insights into the subduction history of Mongol–Okhotsk oceanic crust and its closure. U–Pb dating of zircons from 12 granites previously mapped as Palaeoproterozoic and from three granites reported as Neoproterozoic yield exclusively Phanerozoic ages. These new ages, together with recently reported isotopic dates for the metamorphic and igneous basement rocks, as well as Nd–Hf crustal-residence ages, suggest that it is unlikely that pre-Mesoproterozoic basement exists in the Erguna massif. The geochronological and geochemical results are consistent with a three-stage subduction history of Mongol–Okhotsk oceanic crust beneath the Erguna massif, as follows. (1) The Erguna massif records a transition from Late Devonian A-type magmatism to Carboniferous adakitic magmatism. This indicates that southward subduction of the Mongol–Okhotsk oceanic crust along the northern margin of the Erguna massif began in the Carboniferous. (2) Late Permian–Middle Triassic granitoids in the Erguna massif are distributed along the Mongol–Okhotsk suture zone and coeval magmatic rocks in the Xing’an terrane are scarce, suggesting that they are unlikely to have formed in association with the collision between the North China Craton and the Jiamusi–Mongolia block along the Solonker–Xra Moron–Changchun–Yanji suture zone. Instead, the apparent subduction-related signature of the granites and their proximity to the Mongol–Okhotsk suture zone suggest that they are related to southward subduction of Mongol–Okhotsk oceanic crust. (3) A conspicuous lack of magmatic activity during the Middle Jurassic marks an abrupt shift in magmatic style from Late Triassic–Early Jurassic normal and adakite-like calc-alkaline magmatism (pre-quiescent episode) to Late Jurassic–Early Cretaceous A-type felsic magmatism (post-quiescent episode). Evidently a significant change in geodynamic processes took place during the Middle Jurassic. Late Triassic–Early Jurassic subduction-related signatures and adakitic affinities confirm the existence of subduction during this time. Late Jurassic–Early Cretaceous post-collision magmatism constrains the timing of the final closure of the Mongol–Okhotsk Ocean involving collision between the Jiamusi–Mongolia block and the Siberian Craton to the Middle Jurassic.  相似文献   

16.
古亚洲洋不是西伯利亚陆台和华北地台间的一个简单洋盆,而是在不同时间、不同地区打开和封闭的多个大小不一的洋盆复杂活动(包括远距离运移)的综合体.其北部洋盆起始于新元古代末-寒武纪初(573~522Ma)冈瓦纳古陆裂解形成的寒武纪洋盆.寒武纪末-奥陶纪初(510~480Ma),冈瓦纳古陆裂解的碎块、寒武纪洋壳碎块和陆缘过渡壳碎块相互碰撞、联合形成原中亚-蒙古古陆.奥陶纪时,原中亚-蒙古古陆南边形成活动陆缘,志留纪形成稳定大陆.泥盆纪初原中亚-蒙古古陆裂解,裂解的碎块在新形成的泥盆纪洋内沿左旋断裂向北运动,于晚泥盆世末到达西伯利亚陆台南缘,重新联合形成现在的中亚-蒙古古陆.晚古生代时,在现在的中亚-蒙古古陆内发生晚石炭世(318~316Ma)和早二叠世(295~285Ma)裂谷岩浆活动,形成双峰式火山岩和碱性花岗岩类.蒙古-鄂霍次克带是西伯利亚古陆和中亚-蒙古古陆之间的泥盆纪洋盆,向东与古太平洋连通,洋盆发展到中晚侏罗世,与古太平洋同时结束,其洋壳移动到西伯利亚陆台边缘受阻而向陆台下俯冲,在陆台南缘形成广泛的陆缘岩浆岩带,从中泥盆世到晚侏罗世都非常活跃.古亚洲洋的南部洋盆始于晚寒武世.此时,华北古陆从冈瓦纳古陆裂解出来,在其北缘形成晚寒武世-早奥陶世的被动陆缘和中奥陶世-早志留世的沟弧盆系.志留纪腕足类生物群的分布表明,华北地台北缘洋盆与塔里木地台北缘、以及川西、云南、东澳大利亚有联系,而与上述的古亚洲洋北部洋盆没有关连,两洋盆之间有松嫩-图兰地块间隔.晚志留世-早泥盆世,华北地台北部发生弧-陆碰撞运动,泥盆纪时,在松嫩地块南缘形成陆缘火山岩带,晚二叠世-早三叠世华北地台与松嫩地块碰撞,至此古亚洲洋盆封闭.古亚洲洋的南、北洋盆最后的褶皱构造,以及与塔里木地台之间发生的直接关系,很可能是后期的构造运动所造成的.  相似文献   

17.
青藏高原南部拉萨地体的变质作用与动力学   总被引:3,自引:0,他引:3  
董昕  张泽明  向华  贺振宇 《地球学报》2013,34(3):257-262
拉萨地体位于欧亚板块的最南缘,它在新生代与印度大陆的碰撞形成了青藏高原和喜马拉雅造山带。因此,拉萨地体是揭示青藏高原形成与演化历史的关键之一。拉萨地体中的中、高级变质岩以前被认为是拉萨地体的前寒武纪变质基底。但新近的研究表明,拉萨地体经历了多期和不同类型的变质作用,包括在洋壳俯冲构造体制下发生的新元古代和晚古生代高压变质作用,在陆-陆碰撞环境下发生的早古生代和早中生代中压型变质作用,在洋中脊俯冲过程中发生的晚白垩纪高温/中压变质作用,以及在大陆俯冲带上盘加厚大陆地壳深部发生的两期新生代中压型变质作用。这些变质作用和伴生的岩浆作用表明,拉萨地体经历了从新元古代至新生代的复杂演化过程。(1)北拉萨地体的结晶基底包括新元古代的洋壳岩石,它们很可能是在Rodinia超大陆裂解过程中形成的莫桑比克洋的残余。(2)随着莫桑比克洋的俯冲和东、西冈瓦纳大陆的汇聚,拉萨地体洋壳基底经历了晚新元古代的(~650Ma)的高压变质作用和早古代的(~485Ma)中压型变质作用。这很可能表明北拉萨地体起源于东非造山带的北端。(3)在古特提斯洋向冈瓦纳大陆北缘的俯冲过程中,拉萨地体和羌塘地体经历了中古生代的(~360Ma)岩浆作用。(4)古特提斯洋盆的闭合和南、北拉萨地体的碰撞,导致了晚二叠纪(~260Ma)高压变质带和三叠纪(~220Ma)中压变质带的形成。(5)在新特提斯洋中脊向北的俯冲过程中,拉萨地体经历了晚白垩纪(~90Ma)安第斯型造山作用,形成了高温/中压型变质带和高温的紫苏花岗岩。(6)在早新生代(55~45Ma),印度与欧亚板块的碰撞,导致拉萨地体地壳加厚,形成了中压角闪岩相变质作用和同碰撞岩浆作用。(7)在晚始新世(40~30Ma),随着大陆的继续汇聚,南拉萨地体经历了另一期角闪岩相至麻粒岩相变质作用和深熔作用。拉萨地体的构造演化过程是研究汇聚板块边缘变质作用与动力学的最佳实例。  相似文献   

18.
班公湖-怒江中特提斯洋的俯冲极性和俯冲时间一直存在争议。作者通过野外地质调查、岩相学、锆石U-Pb年代学及岩石地球化学研究,从西藏班公湖蛇绿混杂岩带中识别出一套早白垩世SSZ型蛇绿岩,岩石组合上主要由辉长岩和玄武岩组成,还有少量的硅质岩和超基性岩。本文对辉长岩进行了全岩主、微量元素地球化学及LA-ICP-MS锆石U-Pb年代学研究。地球化学组成特征显示,辉长岩富集轻稀土元素,重稀土元素平坦,相对富集大离子亲石元素,高场强元素存在一定亏损;Th/Ta比值与岛弧玄武岩相似(Th/Ta1.6),Ta/Hf比值较高(0.1),显示其既保留了俯冲环境的地球化学特征,也提供了伸展构造环境的信息。辉长岩中锆石U-Pb加权平均年龄为129.2±0.4 Ma(MSWD=0.36),该年龄是班公湖-怒江缝合带中迄今报道的最年轻蛇绿岩年龄。结合区域地质背景,认为这套蛇绿岩形成于班公湖-怒江古洋盆西段向南俯冲形成的弧前盆地,而班公湖-怒江古洋盆北向俯冲可能始于早侏罗世,晚侏罗世形成双向俯冲格局,直到早白垩世洋盆关闭,晚白垩世进入陆内构造环境。  相似文献   

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