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1.
《吉林大学学报(地球科学版)》2015,(Z1)
<正>Considerable debate persists as to the tectonic setting of the Tianshan Orogen during the late Paleozoic,with active subduction system and intraplate large igneous provinces as two dominant schools.With aims of providing constraints on this issue,geochronological and geochemical analyses have been carried out on the Late Carboniferous high-Al basaltic lava(HAB)from the Bogda Mountain.These lavas,in conformable contact with 相似文献
2.
Dynamic Features of Angular Unconformity Formation——Extensional and Compressional Angular Unconformities 总被引:3,自引:0,他引:3
LI Zhongquan XU Shihai YING Danlin Han Jianhui State Key Loboratory of Oil Gas Reservoir Geology Exploration Chengdu University ofTechnology Chengdu Sichuan PetroChina Company Limited Southwest Oil Gas Field Company Exploration Development Research Institute Chengdu Sichuan 《《地质学报》英文版》2004,78(1):298-301
Angular unconformity is one of the most direct and strongest evidences for approving the tectonic movements of the earth's crust. Its dynamic genesis process has been understood to be mainly related to the compressional setting for a long time. Especially, in a detailed structural analysis for a specific region, when an angular unconformity is discovered people would regard it as the result of orogenic movements of a certain period or a certain episode and neglect the extensional facts. Based on a dialectical point of view of extension-compression, this paper has proved that angular unconformities can be formed not only in compressional settings, but also in extensional ones. Further more, their geological features are compared and he possible genetic mechanisms for angular unconformity under different dynamic settings are studied. 相似文献
3.
Tectonic Framework of Late Paleozoic Intrusions in Xingxingxia: Implications for Final Closure of South Tianshan Ocean in East Tianshan 总被引:1,自引:1,他引:0
This work carried out systematic geological field investigation, petrography observation, zircon geochronology and whole rock geochemistry on Late Paleozoic intrusions in the Xingxingxia region near the Xinjiang-Gansu provincial boundary, western China, aiming to constrain the Late Paleozoic tectonic framework of the Xingxingxia region and the final closure time of South Tianshan Ocean in the East Tianshan. The Xingxingxia area is located in the east part of the Tianshan orogen, and adjacent to the north of the Tarim Basin. The Late Paleozoic magma activities in the Xingxingxia region can be mainly divided into three stages. The first stage includes intrusive magma activities under a collision setting between Late Ordovician to the Late Devonian. The second stage is intrusive magma activities under a subduction setting during(304±3)–(278±3) Ma, and the third stage involves intrusive magma activities under a collision and post-collision setting during(268±5)–(259.9±2.6) Ma. The final suture zone of South Tianshan Ocean should be between the Central Tianshan Block and South Tianshan accretionary complex. Based on previous work, both the first stage magma activities(i.e., intrusive magmatic activities between the Late Ordovician to Late Devonian) and the Hongliuhe ophiolitic complex indicate a close event between Central Tianshan Block and South Tianshan Accretionary Complex. The 304±3 Ma dioritic metamorphic gneiss of the XingX ingxia complex and the 278±3 Ma diorite are all island arc calc-alkaline rocks, the 289±3 Ma gabbro is island arc tholeiitic gabbro formed by magma from metasomatic enrichment mantle. All these results indicate that the second stage of magmatic activities is under a subduction setting. The third stage magma activities i.e. the granitic magma activities of(268±5)–(259.9±2.6) Ma occurred at a transitional setting from compressional to post-collision extensional tectonic setting. Thus, around(268±5)–(260±3) Ma, the final closure of the South Tianshan Ocean occurred and the Tianshan orogen shifted into the intracontinental evolution stage. During and after the closure process, a wide range of metamorphism and large dextral strike-slip faults developed. 相似文献
4.
《地学前缘(英文版)》2020,11(5):1533-1548
The Chinese North Tianshan(CNTS) in the southern part of the Central Asian Orogenic Belt(CAOB) has undergone multistage accretion-collision processes during Paleozoic time,which remain controversial.This study addresses this issue by tracing the provenance of Late Paleozoic sedimentary successions from the Bogda Mountain in the eastern CNTS through U-Pb dating and Lu-Hf isotopic analyses of detrital zircons.New detrital zircon U-Pb ages(N=519) from seven samples range from 261±4 Ma to 2827±32 Ma.The most prominent age peak is at 313 Ma and subordinate ages vary from 441 Ma to 601 Ma,with some Precambrian detrital zircon ages(~7%) lasting from 694 Ma to 1024 Ma.The youngest age components in each sample yielded weighted mean ages ranging from 272±9 Ma to 288±5 Ma,representing the maximum depositional ages.These and literature data indicate that some previously-assumed "Carboniferous"strata in the Bogda area were deposited in the Early Permian,including the Qijiaojing,Julideneng,Shaleisaierke,Yangbulake,Shamaershayi,Liushugou,Qijiagou,and Aoertu formations.The low maturity of the sandstones,zircon morphology and provenance analyses indicate a proximal sedimentation probably sourced from the East Junggar Arc and the Harlik-Dananhu Arc in the CNTS.The minor Precambrian detrital zircons are interpreted as recycled materials from the older strata in the Harlik-Dananhu Arc.Zircon E_(Hf)(t) values have increased since ~408 Ma,probably reflecting a tectonic transition from regional compression to extension.This event might correspond to the opening of the Bogda intraarc/back arc rift basin,possibly resulting from a slab rollback during the northward subduction of the North Tianshan Ocean.A decrease of zircon ε_(Hf)(t) values at ~300 Ma was likely caused by the cessation of oceanic subduction and subsequent collision,which implies that the North Tianshan Ocean closed at the end of the Late Carboniferous. 相似文献
5.
Central Asian Orogenic Belt(CAOB) is one of the largest accretionary orogenic belts in the world. The eastern segment of CAOB is dominated by Paleozoic Paleo Asian Ocean tectonic regime, Mesozoic Paleo-Pacific tectonic regime and Mongolian-Okhotsk tectonic regime. The Songliao and Jiamusi blocks are located in the easternmost part of the CAOB and are the key region to solve the problem about overprinting processes of multiple tectonic regimes. It is generally believed that the Mudanjiang Ocean between the two blocks was finally closed in the Mesozoic, but the Paleozoic magmatism also developed along the Mudanjiang suture zone, while on both sides of the suture zone, there were comparable Paleozoic strata, indicating that the two blocks had converged during the Paleozoic, and the evolution history of the two blocks in the Late Paleozoic remains controversial. The Carboniferous-Permian terrestrial strata mainly developed in Binxian, Wuchang and Tieli on Songliao Block, Baoqing and Mishan on Jiamusi Block. Samples from the Songliao and Jiamusi blocks in the Late Carboniferous-Early Permian and Late Permian are collected for comparative analysis. The LAICP-MS zircon U-Pb dating results show that the maximum depositional age of Middle Permian Tumenling Formation and Late Permian Hongshan Formation in Songliao Block is ~260 Ma, while that of Tatouhe Formation and Carboniferous strata in Jiamusi Block are ~290 Ma and ~300 Ma, respectively, which supports the previous stratigraphic division scheme. The age peaks of ~290–300 Ma, ~400 Ma, ~500 Ma appeared in the Late Carboniferous to Early Permian strata of Jiamusi Block and the Middle Permian strata of Songliao Block. The age peak of ~500 Ma in the Middle Permian strata of Songliao Block may come from the Cambrian basement, Mashan Complex, of Jiamusi Block, while the age peaks of ~420–440 Ma in the Carboniferous strata of Jiamusi Block may come from the Silurian magmatic arc in Zhangguangcai Range in the eastern margin of Songliao Block, reflects the history that they had been potential sources of each other, indicating that they may have combined in the Paleozoic. The Hongshan Formation of Songliao Block in the Late Permian lacks the age peak of ~500 Ma, which indicate that Jiamusi Block was not the provenance of Songliao Block in the Late Permian, that is, there was a palaeogeographic isolation between the two blocks. Combined with the ~210 Ma bimodal volcanic rocks developed along the Mudanjiang suture zone reported previously, we believe that the oceanic basin between the Songliao and Jiamusi blocks should have been connected in Late Permian and reopened during Late Permian to Late Triassic. 相似文献
6.
Geochemical Features of the Two Early Paleozoic Ophiolitic Zones and Volcanic Rocks in the Central —Southern Tianshan Region ,Xinjiang 总被引:2,自引:0,他引:2
This paper deals with the geochemical features of the two Early Paleozoic ophiolite zones in the central-southem Tianshan region and the central Tianshan igneous rock belt between them.Study results suggest that the central Tianshan belt was an Ordovician volcanic arc with an affinity of continental crust, and the Kumux-Hongluhe ophiolitic zone that is located on the southern margin of central Tianshan has a crustal affinity to back-arc marginal sea.The Aqqikkudug-Weiya ophiolitic zone is an accretionary boundary between the Tuha continental block and the central Tianshan volcanic arc during Late Silurian to Devoniann;Ordovician ophi-olitic blocks,Silurian flysch sequence and HP metamorphic rock relics are distributed along the Aqqikkudug-Weiya zone.Geochemically,ophiolitic rocks in the Aqqikkudug-Weiya zone have an affinity to oceanic crust,reflecting a tectonic setting of paleo-trench or subduction zone .The Early Carboniferous red molasses were deposited unconformably on the pre-Carboniferous meta-mrophosed and ductile sheared volcanic and flysch rocks,providing an upper limit age of the central and southern Tianshan belts. 相似文献
7.
Paleozoic Accretion-Collision Events and Kinematics of Ductile Deformation in the Eastern Part of the Southern-Central Tianshan Belt, China 总被引:3,自引:0,他引:3
The Tianshan range could have been built by both late Early Paleozoic accretion and Late Paleozoic collision events. The late Early Paleozoic Aqqikkudug-Weiya suture is marked by Ordovician ophiolitic melange and a Silurian flysch sequence, high-pressure metamorphic relics, and mylonitized rocks. The Central Tianshan belt could principally be an Ordovician volcanic arc; whereas the South Tianshan belt, a back-arc basin. Macro- and microstructures, along with unconformities, provide some kinematic and chronological constraints on 2-phase ductile deformation. The earlier ductile deformation occurring at ca. 400 Ma was marked by north-verging ductile shearing, yielding granulite-bearing ophiolitic melange blocks and garnet-pyroxene-facies ductile deformation, and the later deformation, a dextral strike-slip tectonic process, occurred during the Late Carboniferous-Early Permian. Early Carboniferous molasses were deposited unconformably on pre-Carboniferous metamorphic and ductilely sheared rocks, implying t 相似文献
8.
The Dunhuang Block is located in the conjunction area of the Tarim Craton,Central Asian Orogenic Belt.North China Craton.and Tethyan tectonic domain,and is traditionally regarded as a Precambrian crystalline basement block.However,recent research concluded that the Dunhuang Block represents a Paleozoic orogenic belt.The granitoids that outcrop in the Dunhuang Block recorded tectonic-thermal events in both the Early and Late Paleozoic,which are crucial to understand the tectonic evolutionary history of the Dunhuang Block.In this study,we carried out new petrographic,zircon U-Pb geochronological,and geochemical analyses on the Late Paleozoic Yunlinhe granodiorite,and evaluated its petrogenesis,especially in terms of genesis type and the residual rock. 相似文献
9.
The formation process of the Dianqiangui basin, a special basin, occurred after the Caledonian orogeny, in the south of Guizhou, the west of Giamgxo and the southeast of Yunnan, experienced three periods:it began in the Devonian, persisted in the Carboniferous, and became fiercer in the Permian. Controlled by syndepositional fault-zones, varieties of isolated carbonate platforms, large and small, were developed in the of a deep-water basin, namely, an inter-platform ditch. And a special paleogeographical Late Paleozoic pattern marked by “platform-basin-hill-trough” was produced in both the Dianqiangui basin and its adjacent arms. Affected by regional tectonic activities and the global changes in the sea level, the platform carbonates and coal measures superimposed each other cyclically on the attached platform. The reef-building on the isolated platform and the margin of the attached platform corresponds to the development of the shale succession in the deep-water basin. All of these elementary characteristics reflect a regular and sophisticated filling sucoession of the Dianqiangui basin, a result of the dual controls of the regionally tectonic activities and the eustacy.Based on the two elementary features of the third-order sequences, i.e. the regularity of sedimentary-facies succession in space and the simultaneity of environmental changes in time, 25 third-order sequences could be discerned in the Upper Paleozoic strata in the Dianqiangui basin and its adjacent areas. On the basis of the two kinds of facies-changing surfaces and the two kinds of diachronisms in stratigraphic records, the regional Late Paleozoic sequence-sequence-stratigraphic framework in the Dianqiangui basin and its adjacent areas can be established.There are two types of facies-changing surfaces and two types of diachronisms in stratigraphic records: the static type, a result of the change in sedimentary facies in space, and the dynamic type, a remit of the change in time. These two types of facies-changing surfaces led to the generation of the two types of diachronisms: the diachronism of facies-changing surfaces that was formed by the static facies-changing surfaces, and the diachronism of punactuated surfaces that was formed by the dynamic facies-changing surfaces. The two types of facieschanging surfaces and the two types of diachronisms in stratigraphic records are the key to the establishment of the sequence-stratigraphic framework, The sequence boundaries could be divided geologically into four types:tectonic unconformity, sedimentary unconformity,drowned unconformity and their correlative surfaces,All of these four types can be further grouped into exposed punctuated surfaces and deepened punctuated surfaces,The tectonic unconformity in similar to Type Ⅰ sequence boundary,and the sedimentary unconformity is similar to Type Ⅱ sequence boundary defined by Vail et al.In terms of sequence stratigraphy,the tectonic unconformities of the Ziyun movement,the Qiangui epeirogeny and the Dongwu revolution as well as the drowned unconformity in the transitional period from the Permian to the Triassic can be systematically defined and their geological characteristics are briefly presented. 相似文献
10.
This paper presents the end Late Paleozoic tectonic stress field in the southern edge of Junggar Basin by interpreting stress-response structures(dykes,folds,faults with slickenside and conjugate joints).The direction of the maximum principal stress axes is interpreted to be NW—SE (about 325°),and the accommodated motion among plates is assigned as the driving force of this tectonic stress field.The average value of the stress index R’ is about 2.09,which indicates a variation from strike-slip to compressive tectonic stress regime in the study area during the end Late Paleozoic period.The reconstruction of the tectonic field in the southern edge of Junggar Basin provides insights into the tectonic deformation processes around the southern Junggar Basin and contributes to the further understanding of basin evolution and tectonic settings during the culmination of the Paleozoic. 相似文献
11.
西天山伊宁地块主褶皱幕鄯善运动的确立及地质意义 总被引:7,自引:0,他引:7
地层不整合接触是研究地质发展历史及鉴定地壳运动特征和运动时期的重要依据,主褶皱幕是一造山带多幕构造运动中起决定性作用和最为重要的一次构造运动。天山的构造运动幕次多且因地而异,前人认识多有分歧,也没有确立主褶皱幕。伊宁地块伊什基里克山一带上、下石炭统之间为角度不整合接触关系,在岩石组合、沉积环境、古生物地理区系、构造样式、区域大地构造背景等方面差异最为显著,凸显了鄯善运动对区内构造格架和盆山演化起到决定性的作用,因而是主褶皱幕。鄯善运动记录了西天山沟—弧—盆格局消亡,天山残余小洋盆终结,塔里木板块和准噶尔板块最终拼合在一起,形成了统一大陆的重要演化信息。 相似文献
12.
新疆博格达山主体由石炭系海相火山一沉积岩系组成,以发育两期双峰式火山岩,但不发育花岗岩为特征,对其晚古生代地层时代的划分和演化争议较大。本文重点对博格达山北部两个晚古生代砂岩进行了碎屑锆石U-Pb年代学分析,重新标定博格达山地区晚古生代地层的形成时代;利用物源区的演化,约束晚古生代构造演化。测年结果显示博格达上亚群砂岩的碎屑锆石表面年龄值分布范围较宽,主峰年龄为343~284 Ma(80%),次峰年龄为386~375 Ma(3%)、503~441Ma(7%)和871~735 Ma(10%);芦草沟组砂岩的碎屑锆石表面年龄值非常集中,主峰年龄为358~279 Ma(97%),次峰年龄为257~251 Ma(约3%)。博格达山中部原石炭纪博格达群上亚群与西部和南部下芨芨槽群相当,应属于早二叠世,中部一东部的石炭一二叠纪界线应在博格达下亚群一上亚群或居里得能组一沙雷塞尔克组之间的不整合面之中。博格达北部地区晚二叠世以南侧天山物源区供给为主,反映出晚古生代期间博格达山地区至少存在晚石炭世末和中二叠世两期构造隆升。结合区域火山岩与火山碎屑岩的研究,认为博格达山地区晚古生代主要经历4个演化阶段:早石炭世弧后盆地裂解阶段、晚石炭世碰撞拼贴阶段、早二叠世碰撞后伸展阶段、中-晚二叠世再次隆升到稳定阶段。 相似文献
13.
地层不整合接触是研究地质发展历史和鉴定地壳运动特征的重要依据。通过大范围露头尺度和填图尺度不整合面的识别,结合不同时代地层沉积体系的特征及构造变形样式的对比研究,发现东昆仑造山带东段晚古生代—中生代地层由底到顶共发育有4个不同类型的不整合面,分别是上二叠统格曲组与上石炭统浩特洛哇组之间的角度不整合面、中三叠统希里可特组与闹仓坚沟组之间的微角度不整合面、上三叠统八宝山组与下伏不同时代地层之间的角度不整合面、下侏罗统羊曲组与上三叠统八宝山组之间的平行不整合面。这几个不同时代的不整合面分别代表了东昆仑东段晚古生代—中生代地质演化时期中特定的构造事件。其中,格曲组与浩特洛哇组角度不整合关系代表东昆仑造山带南缘阿尼玛卿—布青山古特提斯洋晚二叠世开始向北俯冲的构造事件;希里可特组与闹仓坚沟组微角度不整合关系与陆(弧)陆局部差异性初始碰撞的洋陆转换构造事件密切相关;八宝山组与下伏不同时代地层角度不整合关系是东昆仑地区分布较广、意义重大的一个不整合面,代表中三叠世晚期—晚三叠世早期东昆仑地区陆(弧)陆全面碰撞的主造山构造事件,同时该期碰撞造山事件铸就了东昆仑及其周缘地区的基本构造格架。羊曲组与八宝山组之间平行不整合面则与晚三叠世晚期—早侏罗世早期陆内演化过程中地壳垂向抬升事件相关。这些不整合面的厘定及其代表的相应构造事件对于合理建立东昆仑地区晚古生代—中生代构造演化过程具有重要意义。 相似文献
14.
Tarim Basin is the large, very complex, oil-bearing basin in China, surrounded by the Tianshan–Beishan, West Kunlun and Altyn Tagh mountain belts to the north, south, and southeast, respectively. Understanding the processes and evolution of this complex superimposed basin, especially with respect to the effects of single tectonic movements, is a difficult challenge, which concerns the tectonic and dynamic interrelationships between the basin and the orogenic belts during the different stages of the Paleozoic in the Paleo-Asian and Tethyan tectonic systems and for the evaluation of the resource potentials in Tarim Basin. In this study, we focused on 3-dimensional, basin-scale structural architecture and the properties of two regional unconformities that occur within the basin and its adjacent areas. Here, we outline the structural deformations underlying the unconformity, the structural architecture styles and the distributions of the unconformity, and the stratigraphic sequence and nature of the sedimentary rocks immediately overlying the unconformity. During the late Early and Middle Paleozoic tectonic movements, disconformities developed mainly in the northern and the central parts of the basin, and angular unconformities which beneath layers were monocline and faulted-fold deformations developed in the southern, or the southern and northern parts of the basin, respectively. Before the Silurian, the Low Hotian Uplift, the NE-trending faulted-folded belts of the Tangguzibas Depression and the southern Tazhong Uplift underwent intense deformation related to SE–NW-directed tectonic compression. In addition, the NE-trending faults in the Tangguzibas Depression developed during periods of activity on the South Altyn Tagh Fault. The structural deformation, as well as the depositional facies, formed in response to the subduction and closure of the South Altun Ocean and West Kunlun–Kudi Ocean, and the resulting collisional orogeny. Prior to deposition of Upper Devonian sediments, structural deformation and erosion occurred in two marginal parts of the basin. The extent and intensity of deformation on the NE-trending faults in the Tangguzibas Depression were also reduced, whereas the NE-trending folds developed in the Manjiaer Depression. The Tabei Uplift experienced uplift and deformation. The closure of the North Altun Ocean and the eastern part of the South Tianshan Ocean with south-subduction may be the main driving forces for the tectonic activity. Extensive areas in the northern and southern margins of the basin were uplifted and denudated by orogenic activity as a prelude to the molasse basin that developed in the early Late Devonian in the northeastern and southeastern parts of the basin. The structural architecture of the unconformities reveals the geometry and dynamics of the basin–orogen system in single tectonic movements. 相似文献
15.
顺托果勒低隆及邻区加里东中期运动面的结构特征、区域分布规律及其构造性质具有重要的研究意义。本文运用钻井资料分析、地震资料解释等对研究区加里东中期运动面进行研究,结果表明:1)研究区加里东中期3个幕次的构造运动导致3个运动面的形成:Ⅰ幕运动面由塔中地区的O3l/前O3l角度不整合面、顺托果勒到塔北地区的O3q/O2yj平行不整合面组成,Ⅱ幕运动面为O3s (或O3qr)与下伏碳酸盐岩构成的同构造沉积超覆型角度不整合面,Ⅲ幕运动面为S/O角度不整合面,在隆起区存在显著的构造削截特征。2)3个运动面的结构特征和差异分布规律具有明确的构造指示意义:Ⅰ幕、Ⅲ幕运动面属于典型的构造成因不整合面,形成于周缘洋盆关闭、陆块碰撞造山时期;Ⅱ幕运动面的形成则受到早期构造格局、全球海平面上升及盆地南缘碰撞造山作用的综合控制。3)顺北、顺南地区地震剖面中存在沿鹰四段顶面以下顺层规律分布的“串珠”反射,推测属于准同生岩溶洞穴。 相似文献
16.
东北及邻区晚古生代地层接触关系与佳-蒙地块的形成和演化 总被引:1,自引:0,他引:1
东北及邻区晚古生界及其相关地层间的接触关系含有丰富的大地构造信息,本文系统梳理了这些资料,用以阐述佳-蒙地块的形成与演化。佳-蒙地块南缘的西别河组、北缘的卧都河组及东缘的黑台组等晚志留世—早泥盆世地层底部均发育不整合(或非整合),揭示了东北地区曾经历了一次十分重要的大地构造运动,标志着佳-蒙地块的形成。区内泥盆纪—石炭纪和石炭纪—二叠纪地层之间多为整合接触,说明这一时期佳-蒙地块处于稳定沉降接受沉积阶段。佳-蒙地块南缘晚二叠世林西组底部的平行不整合界面及其上部的磨拉石建造,以及中—晚二叠世地层序列由海相向陆相的转化,表明林西组处于前陆盆地的沉积环境,标志着佳-蒙地块与华北板块发生碰撞拼合。佳-蒙地块南缘早三叠世卢家屯组底部的不整合及卢家屯组下部砾岩所具有的磨拉石建造特征,说明碰撞造山作用仍在持续进行,属于递进造山作用。晚三叠世大酱缸组底部的不整合,说明造山作用已经完成,佳-蒙地块独立发展的历程结束。 相似文献
17.
塔里木地块与古亚洲/特提斯构造体系的对接 总被引:32,自引:15,他引:17
塔里木盆地为环形山链所环绕,北缘为古亚洲体系的天山弧形山链,南缘为特提斯体系的西昆仑-阿尔金弧形山链。自新元古代晚期以来,塔里木地块及周缘地区经历了古亚洲洋盆和特提斯洋盆的开启、俯冲、闭合以及微陆块多次碰撞造山,发生多期的构造、岩浆及成矿作用。特别是受印度/亚洲碰撞(60~50Ma)以来的近程效应和远程效应影响,使塔里木盆地周缘发生强烈的隆升、缩短及走滑变形,形成了现今复杂的环型造山系,完成了古亚洲体系和特提斯体系与塔里木地块的最终对接。塔里木地块与周缘两大构造体系的焊接是从早古生代开始的。研究表明,早古生代末期塔里木已与西昆仑-阿尔金始特提斯造山系链接一起。此时,塔里木地块东段与中天山增生弧地体碰撞,而西段在晚古生代与中天山增生弧地体碰撞。塔里木盆地周缘早古生代造山系中存在早古生代中期和早古生代晚期的两次造山事件,致使塔里木盆地内映现两个早古生代构造不整合面:晚奥陶世-志留纪之间的角度不整合和中晚泥盆世与早古生代之间的角度不整合。塔里木盆地早古生代的古地理、古环境和古构造研究表明,塔里木早古生代台地位于盆地的中西部,盆地东部为陆缘斜坡和深海/半深海沉积盆地,与南天山早古生代被动陆缘链接。印度/亚洲碰撞导致塔里木盆地西南缘的喜马拉雅西构造结的形成与不断推进,使特提斯构造体系与古亚洲构造体系在西构造结处靠拢及对接,终使塔里木盆地最后定型。 相似文献
18.
位于中亚造山带西段和塔里木克拉通之间的天山造山带的古生代构造演化历史目前还存在很大争议,其广泛发育的古生代岩浆岩则是揭示俯冲增生过程和构造体制转换的重要岩石探针.本文对我国西天山巴仑台地区的7个古生代岩浆岩进行了系统的年代学和地球化学研究.LA-ICP-MS锆石U-Pb定年限定它们的结晶年龄在319~307 Ma之间,均形成于晚石炭世.地球化学特征显示晚石炭世的镁铁质岩浆岩主要起源于软流圈地幔或者受俯冲交代富集的岩石圈地幔;而同期花岗质岩石总体上均属于准铝质?弱过铝质的中钾钙碱性和高钾钙碱性I型花岗岩,主要起源于下地壳基性岩的部分熔融.根据西天山地区古生代岩浆岩的时空分布规律及变质岩、蛇绿岩和沉积岩的研究成果,本文提出320~310 Ma的岩浆岩形成于板片断离的构造背景,标志着由大陆碰撞向后碰撞的构造体制转换;而310~307 Ma的岩浆岩形成于后碰撞伸展的构造背景. 相似文献
19.
《International Geology Review》2012,54(11):1058-1066
The plate-tectonic evolution of the Tarim basin and nearby western Tianshan region during Paleozoic time is reconstructed in an effort to further constrain the tectonic evolution of Central Asia, providing insights into the formation and distribution of oil and gas resources. The Tarim plate developed from continental rifting that progressed during early Paleozoic time into a passive continental margin. The Yili terrane (central Tianshan) broke away from the present eastern part of Tarim and became a microcontinent located somewhere between the Junggar ocean and the southern Tianshan ocean. The southern Tianshan ocean, between the Tarim craton and the Yili terrane, was subducting beneath the Yili terrane from Silurian to Devonian time. During the Late Devonian-Early Carboniferous, the Tarim plate collided with the Yili terrane by sinistral accretional docking that resulted in a late Paleozoic deformational episode. Intracontinental shortening (A-type subduction) continued through the Permian with the creation of a magmatic belt. 相似文献