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1.
云开地块东缘粤西圭岗镇附近寒武系之上不整合覆盖一套灰白色石英砾岩-含砾砂岩,由于缺乏化石和年龄依据,这套岩石的时代长期存有争议.利用LA-ICP-MS U-Pb测年手段,对该套含砾碎屑沉积岩及其上下层位进行了U-Pb测年,4件样品共获得300组有效数据,年龄变化于2 900~400 Ma,不整合面之下样品主要集中于1 100~700 Ma,不整合面之上最年轻碎屑锆石年龄集中于450~400 Ma.新的测年数据结合前人研究成果表明,云开地块东缘不整合面下伏及上覆地层的时代分别为寒武纪和泥盆纪.研究区寒武纪时期物源特征与印度、东南极洲和澳大利亚西部相似,指示该时期研究区同冈瓦纳东北缘相连,物源来自东冈瓦纳北缘南极洲、印度地块和澳大利亚之间的造山带,而泥盆纪物源主要来自邻近的云开地块.寒武系和泥盆系之间的不整合面是早古生代郁南运动与广西运动叠加的产物. 相似文献
2.
华南加里东运动初探 总被引:12,自引:0,他引:12
华南加里东运动包含了郁南运动、北流运动(崇余运动)和广西运动,具多幕陆内造山特点。其影响范围包括扬子板块东缘"江南隆起"以东、以南广大地区。华南加里东构造带总体呈东西向展布,南部桂西右江盆地-粤南地区泥盆系不整合于下伏的寒武系之上,中部桂东-粤中-闽西-赣南-湘南地区泥盆系不整合于奥陶系之上,靠近"江南隆起"的湘中-浙西地区泥盆系不整合于志留系之上,但钦防盆地志留系与泥盆系整合接触。寒武系-志留系为同造山盆地的复理石沉积。从寒武纪-志留纪同造山盆地由南向北迁移,盆地展布、物源供给等显示"南山北盆"的盆山格局和造山带"由南向北"挤压的趋势。 相似文献
3.
全球早古生代造山带(Ⅲ):华南陆内造山 总被引:6,自引:0,他引:6
华南早古生代加里东期变形、岩浆、沉积等特征表现为陆内造山带特征。通过对加里东期角度不整合分布、褶皱、断裂逆冲极性等特征的分析,发现大明山、大瑶山地区EW轴向的寒武系褶皱不对称性和角度不整合空间上向北的拓展变新规律,指示晚寒武世—早奥陶世的由南向北推覆挤压可能是云开、滇—桂北越地块依次向北推挤的结果;从全球背景看,可能和华南陆块南部一些地块与冈瓦纳大陆北缘依次碰撞接触导致的远程陆内效应有关。然而,湘赣边境、桂北元宝山及越城岭地区的早古生代NE向褶皱不对称性指示向西拓展,这可能是由于华夏地块与扬子地块在晚奥陶世—早志留世沿郴州临武断裂陆内收缩挤压的结果,其全球背景可能和华南陆块顺时针旋转与冈瓦纳全面碰撞相关。总之,加里东期构造运动总体由南向北、由东向西渐新,变形强度由强到弱的特征,反映华南陆内碰撞造山事件的根本原因是其与冈瓦纳北缘碰撞的远程效应。450~420 Ma华南已经属于冈瓦纳北缘一部分。 相似文献
4.
加里东运动构造古地理及滇黔桂盆地的形成--兼论滇黔桂盆地深层油气勘探潜力 总被引:14,自引:0,他引:14
中国南方的滇黔桂地区,早古生代与晚古生代之交曾经发生过较为强烈的加里东运动,包括三个幕:寒武纪末期的郁南运动,中、奥陶世末期的都匀运动以及志留纪末期的广西运动;奥陶系与志留系的残留不全和晚奥陶世至志留纪大片古陆———滇黔桂古陆的展布是加里东运动的重要体现。志留纪末期的广西运动之后,在大致相当于早古生代“滇黔桂古陆”分布的地区形成一个特殊的“滇黔桂盆地”,而且在滇黔桂盆地的主体部位常常是泥盆系直接覆盖在寒武系之上。寒武系,特别是下寒武统,由于寒武纪初期的快速海侵作用而在研究区域普遍发育烃源岩系;研究区域的泥盆系,特别是中泥盆统,在台间盆地中发育优质烃源岩。因此,巨大的构造古地理演变和海陆变迁,形成了一个晚古生代的泥盆系优质烃源岩与早古生代的下寒武统优质烃源岩的空间叠合区域,该叠合区域的加里东运动不整合面上、下的储集体即成为该地区的深层油气勘探对象,预示着滇黔桂盆地的深层存在较大的油气勘探潜力。 相似文献
5.
青藏高原东南缘滇西早古生代早期造山事件 总被引:22,自引:10,他引:12
野外观察、LA-ICP-MS锆石U-Pb测年和Hf同位素分析结果表明:青藏高原东南缘滇西芒市地区存在奥陶系底砾岩与前寒武-寒武系之间的地层不整合;龙江眼球状片麻岩锆石边部U-Pb年龄约为502 ~ 518Ma,代表原岩花岗岩结晶时代;继承性锆石核部具有与拉萨地体相似的年龄谱,说明早古生代早期腾冲地体与拉萨地体属于统一陆块;锆石边部具有负的、变化范围较大的εHf(t)值(-15.7 ~-2.0),结合眼球状片麻岩野外、岩相学特征及区域构造背景说明原岩花岗岩来源于古老地壳部分熔融,并伴随不同程度幔源物质的注入,可能为岩浆弧的一部分.综合野外观察及锆石同位素研究结果,明确了青藏高原东南缘存在早古生代早期造山事件.与喜马拉雅、拉萨、羌塘等地体的同一时代构造事件对比,认为青藏高原东南缘滇西地区早古生代早期造山带为形成在冈瓦纳大陆北缘的安第斯型造山带的一部分,为认识冈瓦纳大陆北缘早古生代演化提供新的证据. 相似文献
6.
青藏高原泛非—早古生代造山事件研究重大进展——冈底斯地区寒武系和泛非造山不整合的发现 总被引:13,自引:2,他引:11
在申扎地区发现了较为完整的寒武纪地层和奥陶系与寒武系之间的"泛非运动"角度不整合。这是迄今为止青藏高原南部发现的唯一确切的寒武纪地层,不但进一步丰富和健全了青藏高原的地层系统,而且也是在青藏高原和周边发现的唯一的下奥陶统与寒武系"泛非运动"角度不整合界面。通过对申扎"泛非运动"界面的研究,可以准确界定"泛非运动"的时限及其动力学过程,也是研究"泛非运动"之前冈瓦纳大陆北缘沉积作用不可替代的标本,对青藏高原构造演化研究具有重要、深远的意义。 相似文献
7.
中央造山带早古生代地体构架与高压/超高压变质带的形成 总被引:57,自引:2,他引:57
位于北中国板块群与南中国板块群之间的中央造山带是中国大陆一条十分醒目而又极其重要的巨型(长达5000km)构造带。中央造山带是经历了大致600Ma的活动历史,和泥盆纪、三叠纪的两次主要碰撞造山以及白垩纪以来的陆内造山过程而构筑成的典型的“复合造山带”。特别是巨型中央超高压变质带及其两期超高压变质作用的发现,揭示了中央造山带的形成还经历了板块会聚边界洋壳/陆壳深俯冲的两次壮观地质事件。位于中央造山带北部的“北中央早古生代造山带”具有“多地体、多岛弧”的地体构架和“多俯冲和多碰撞造山”的动力学作用。研究认为北中央早古生代多地体/岛弧群是冈瓦纳超大陆西侧(或西北侧)陆块/岛弧群的组成部分,其主要的证据是:1北中央寒武系—志留系的过渡性动物群性质反映早古生代古生物区系与始特提斯洋盆海水相通的古地理环境;2北中央诸多蛇绿岩带形成时代>500~540Ma(新元古代-奥陶纪)可作为始特提斯洋盆扩张时限的印证;3多岛弧带为北中央早古生代地体的陆缘增生带,形成于540~450Ma,岛弧带形成自南(外)而北(里)渐新的趋势表明与始特提斯洋盆相连接的弧前小洋盆逐级俯冲的特征;4北中央早古生代多地体/岛弧群的“弧/陆碰撞”及早古生代造山带的形成是中晚泥盆世(420Ma)冈瓦纳超大陆边部古特提斯洋盆初始扩张的产物。研究表明在500~440Ma形成的柴北缘-南阿尔金超高压变质带与始特提斯弧前小洋盆的俯冲继而地体陆壳的深俯冲有关。 相似文献
8.
全球早古生代造山带(Ⅰ):碰撞型造山 总被引:6,自引:0,他引:6
自新元古代罗迪尼亚超大陆裂解以来,早古生代是板块构造运动活跃时期,具有板块运动速度较快、构造格局不稳定、块体之间相互作用复杂多变等特征,造山带演化极其复杂,导致全球早古生代古大陆重建现今仍较模糊。特别是,早古生代末450~400 Ma存在全球性准同时的造山运动,已经出现俯冲增生、碰撞、陆内3种类型的全球尺度造山带。本文侧重论述全球早古生代碰撞类型造山带的特征,总结典型碰撞造山带最新的年代学、变质、变形和岩浆作用特征及其时空分布。早古生代全球碰撞型造山带主要分布在南半球的泛非造山带和北半球的加里东期造山带,分别与南方冈瓦纳大陆和北方劳俄古陆的初步集结密切相关,早古生代碰撞造山主要体现在大陆块之间的碰撞作用为特征。这些早古生代碰撞造山带具有近似的碰撞年龄,大致相同的演化过程。其中,南方大陆主体碰撞完成于540 Ma,而北方大陆主体集结完成于420 Ma,从全球构造意义上可能意味着全球一个420~400 Ma的超大陆初步形成。 相似文献
9.
《地球科学进展》2016,(4)
喜马拉雅造山带中段的吉隆和聂拉木地区出露一套眼球状片麻岩,其矿物组成为石英、钾长石、斜长石、黑云母和少量的白云母。片麻岩中锆石发育典型的岩浆韵律环带,LA-ICP-MS锆石U-Pb测年显示,2件样品中岩浆锆石的加权平均年龄分别为(488.5±1.1)Ma,(475.1±0.7)Ma和(468.1±2.5)Ma,代表研究区早古生代早期的岩浆作用。现有的早古生代地质记录表明,喜马拉雅地体存在早古生代造山事件,这一事件可与青藏高原南部和东南部的拉萨、羌塘、保山和腾冲地体内同一时代的构造热事件对比,指示区域早古生代造山作用。早古生代早期的造山作用是冈瓦纳大陆聚合之后,原特提斯洋岩石圈沿冈瓦纳大陆北缘俯冲调整的安第斯型造山作用的产物,而非超大陆内部块体拼合过程中陆—陆碰撞为主要特征的泛非造山作用。 相似文献
10.
哈拉奇地区位于西南天山南侧、塔里木盆地西北缘,是塔里木板块和哈萨克斯坦一西伯利亚板块碰撞的前锋区域。出露了寒武纪-二叠纪变质程度较浅的地层;新发现其存在奥陶系-志留系平行不整合、泥盆系-石炭系平行不整合和二叠系-中、新生界角度不整合共3个不整合面,并以阿尔帕确依切克穹窿式复背斜为界,两侧志留系-二叠系沉积环境存在较大差异,组成背斜的奥陶系、寒武系与上覆地层变质作用也不同。奥陶系-志留系平行不整合与区域上祁连运动相对应;泥盆系-石炭系平行不整合同天山运动中期相吻合;二叠系-中、新生界角度不整合为天山运动末期的影响造成。 相似文献
11.
秦岭褶皱带位于华北板块和扬子板块结合部位,其在河南省内的部分多划为东秦岭。东秦岭以商南-镇平缝合带分为东秦岭北部和东秦岭南部。东秦岭古生代生物古地理演变可以划分为6个阶段。在寒武纪至中奥陶世早期,东秦岭北部二郎坪海槽的寒武纪放射虫和早奥陶世牙形石与东秦岭南部淅川陆棚北部的寒武纪三叶虫、早奥陶世牙形石和头足类属华南生物省,而淅川陆棚南部的寒武纪三叶虫和早奥陶世牙形石属于华南生物省,兼有华北生物省分子。在中奥陶世晚期至奥陶纪末,二郎坪海槽的腹足类、头足类和珊瑚与淅川陆棚的牙形石、珊瑚、腕足类、头足类和三叶虫均属华北生物省。在早志留世,二郎坪海槽的珊瑚与淅川陆棚的笔石属华南生物省。在中志留世至早泥盆世,东秦岭未发现古生物化石,很可能为陆地,并与华北陆块联为一体。在中泥盆世至早石炭世,东秦岭北部柿树园海槽与东秦岭南部南湾海槽的孢子及淅川陆棚的晚泥盆世珊瑚、腕足类和古植物及早石炭世蜓属华南生物省。晚石炭世至二叠纪末,柿树园海槽的孢子见于华北生物省,东秦岭南部缺乏海相沉积。总之,在古生代,东秦岭经历了由华南生物省→华北生物省→华南生物省→华北陆→华南生物省→华北生物省6个阶段,组成3个演变旋回。东秦岭北部和南部生物古地理具有明显的演变方向的统一性和演变时间的相似性。 相似文献
12.
Binsong Zheng Renjie Zhou Xiuping Wang Zhaohui Xiao Yao Chen 《International Geology Review》2020,62(10):1262-1272
ABSTRACT The intraplate Kwangsian Orogeny is a key orogenic event in South China in the mid-Paleozoic. We re-examined the evidence for the Yichang Uplift, an inferred geographic feature during the Kwangsian Orogeny, to evaluate its timing and nature. Field, sedimentological, mineralogical and geochronological data were collected from the Late Ordovician-Early Silurian Xiaohe section, Hunan-Hubei area. Results suggest that the Xiaohe section is composed of the Late Ordovician Wufeng Formation black shale in the lower part and the Early Silurian Longmaxi Formation black shale in the upper part. We found that the clay layers interbedded in the Wufeng Formation are altered rhyolitic tuffs instead of parts of a subaerial wreathing crust. LA-ICP-MS U-Pb dating of zircons in the top tuff layer of the Wufeng Formation yielded an age of 447.0 + 1.4/- 2.2 Ma, consistent with biostratigraphic data, providing a radiometric constraint for the sedimentary break existed between the Wufeng and Longmaxi formations and confirming the absence of the Hirnantian (latest Ordovician) Guanyinqiao Formation in the study area. Our data support that the Yichang Uplift was a submarine highland possibly initiated by the reactivation of the inherited Jianshi-Enshi Fault in the Hunan-Hubei area during the Kwangsian Orogeny. 相似文献
13.
Jean-François Ghienne Julien Moreau Lionel Degermann Jean-Loup Rubino 《International Journal of Earth Sciences》2013,102(2):455-482
The stratigraphic record of the eastern Murzuq Basin has been importantly influenced by deformation resulting in angular and/or deeply erosional unconformities, though the overall context is intracratonic. Major transgressive events and the Ordovician glaciation are nevertheless documented, allowing the delineation of tectonic-, eustasy- or climate-driven unconformities. Lower Palaeozoic key events and related unconformities that characterize the North Gondwana platform have therefore a signature in the eastern Murzuq Basin. The basement/cover unconformity, also known as the infra-Tassilian surface, truncates all the deformed and metamorphosed Lower Cambrian and older rocks. Above is a ?Middle Cambrian to Lower Ordovician megasequence (Murizidié and Hasawnah Fms.), which is in turn truncated by an intra-Ordovician, angular unconformity. This megasequence is unconformably overlain by a Middle Ordovician (Hawaz Fm.) to Silurian (Tanzzuft and Akakus Fms) megasequence, which includes the Upper Ordovician glaciogenic unit (Mamuniyat Fm.), bounded at the base by a polygenic glacial erosion surface showing corrugated glacial lineations, tillites, and glaciotectonic structures. The Middle Ordovician to Silurian megasequence is finally truncated by a base-Devonian, angular unconformity overlain by fluvial sandstones. Regarding the possibility that those fluvial deposits may be as younger as Late Devonian in the eastern Murzuq Basin based on palaeoflora, the so-called Caledonian unconformity might be here a much younger (mid-Eifelian?) surface, and the occurrence of the Lower Devonian “Tadrart Fm.” is questioned. The Upper Ordovician glacial erosion surface, which is sometimes referred to as the Taconic unconformity, usually truncates Middle Ordovician strata in the Murzuq Basin but reaches significantly deeper stratigraphic levels in places that have been previously involved in the intra-Ordovician deformation event. In the Murizidié (southeastern Murzuq Basin), the infra-Tassilian surface, the intra-Ordovician unconformity, and the Upper Ordovician glacial erosion surface amalgamate together. Here, an estimate of the glacial erosion depth cannot be derived from the stratigraphic hiatus beneath the glacial incision, the main part of which relate to the intra-Ordovician tectonic event. The Upper Ordovician climate-related glacial erosion surface is not a valid unconformity for a sequence hierarchy framework of the Lower Palaeozoic, although it presents most of the physical attributes of tectonic-driven unconformities. 相似文献
14.
To better constrain the Early Paleozoic tectonic evolution of the western part of the Erguna–Xing’an Block, detrital zircon U–Pb dating was applied on the Ordovician to Devonian sedimentary strata along the southeast part of the China–Mongolia border. Most of the zircons from five sedimentary samples display fine-scale oscillatory growth zoning and Th/U ratios higher than 0.1, indicating a magmatic origin. All five Ordovician–Devonian samples display the similar age distribution patterns with age groups at ∼440 Ma, ∼510 Ma, ∼800 Ma, ∼950 Ma, and few Meso- to Paleo-Proterozoic and Neoarchean grains. This age distribution pattern is similar to those from adjacent blocks in the southeastern Central Asian Orogenic Belt. Considering previous tectonic studies, we propose bidirectional provenances from the Erguna–Xing’an Block and Baolidao Arc.Consequently, a new model was proposed to highlight the Early Paleozoic tectonic evolution of the western Erguna–Xing’an Block, which constrains two main Early Paleozoic tectonic events of the Xing-Meng Orogenic Belt: (a) pre-Late Cambrian collision between Erguna–Kerulen Block and Arigin Sum-Xilinhot-Xing’an Block; (b) the Early Paleozoic subduction of Paleo-Asian Ocean and pre-Late Devonian collision between Erguna–Xing’an Block and Songliao-Hunshandake Block. 相似文献
15.
Emyr Williams 《Tectonophysics》1978,48(3-4)
In western Tasmania Eocambrian and Cambrian rock sequences accumulated in narrow troughs between and within Precambrian regions which became geanticlines. The largest trough is meridional and is flanked by the Tyennan Geanticline to the east and the Rocky Cape Geanticline to the west. Within this trough ultramafic and mafic igneous masses, some of which are dismembered ophiolites, occur below a structurally conformable but erosional surface. This surface is at the base of an early-Middle Cambrian turbidite sequence, which grades upward into a probable correlate of the Owen Conglomerate that ranges into the Ordovician. Fault-bounded areas of Rocky Cape strata occur at the eastern boundary of the sedimentary trough deposits. A considerable pile of mineralized calcalkalic volcanic material, in which granite was emplaced, accumulated between the sedimentary trough deposits and the Tyennan Geanticline. Movements along Cambrian faults near and parallel to the margin of the Tyennan Geanticline caused angular unconformities. Above the unconformities occur volcaniclastic sequences that pass conformably upward into shallow marine and terrestrial Owen Conglomerate, derived from the Tyennan Geanticline.The transgressive Owen Conglomerate and its correlates are followed conformably by shallow marine limestone, of Early to Late Ordovician age. These limestone deposits covered much of western Tasmania and are succeeded conformably by Silurian to Early Devonian beds of shallow-marine quartz sandstone and mudstone.Pre-Middle Devonian rocks of western Tasmania extend to the Tamar Tertiary trough. In the northeast of Tasmania, immediately to the east of the Tamar trough, are sequences of interbedded mudstone and turbidite quartz-wacke of the Mathinna Beds, ranging in age from Early Ordovician to Early Devonian.The Cambrian to Early Devonian rocks of Tasmania are extensively deformed and show flattened parallel folds. In western Tasmania the folds are dated as late-Early to early-Middle Devonian because fragments of the deformed rocks occur in undisturbed Middle Devonian terrestrial cavern fillings. Folds of the northeastern Tasmania Mathinna Beds are probably of the same age. This widespread Devonian deformation is correlated with the Tabberabberan Orogeny of eastern Australia.In western Tasmania the geanticlines of Cambrian times behaved as relatively competent blocks during the Devonian folding, which is of two main phases. In the earlier phase the competent behaviour of the Tyennan Block determined the fold patterns. In the north the dominantly later folds resulted from movement from the northeast. During this later Devonian phase the Tyennan Block yielded in a northwesterly trending narrow zone of folding.In northeast Tasmania the Mathinna Beds exhibit folds which indicate a tectonic transportation opposite in direction to that which resulted in the folds of similar age in western Tasmania.Granitic rocks, dated 375-335 m.y., were emplaced within the folded rocks of Tasmania with usually sharp, discordant contacts. Foliations in the batholiths of northeast Tasmania suggest post-intrusion deformations involving east—west flattening. The late deformations may be related to lateral movements along a fracture zone which brought the Mathinna Beds of northeast Tasmania into juxtaposition with the rocks of contrasting stratigraphical and structural characteristics of western Tasmania.Flat-lying Late Carboniferous and younger deposits rest unconformably on the older rocks. 相似文献
16.
新疆古生代构造—生物古地理 总被引:4,自引:0,他引:4
通过6幅图表达了新疆古生代板块的构造-生物古地理区系。早古生代,包括劳伦,波罗的、西伯利亚和哈萨克斯坦4陆块的亚帕特斯古陆(Iapetusa)群,与由其余陆块构成的冈瓦纳古陆群隔原特提斯洋相对峙。石炭-二叠纪,欧美、安加拉、太平洋和冈瓦纳4古陆共存并立。西伯利亚和哈萨克斯担板块经历了早古生代亚伯特斯古陆、晚古生代安加拉古陆和早二叠世晚期以来欧亚大陆3个发展阶段。塔里木、中朝、华南-东南亚板块经历了早古生代冈瓦纳古陆、晚古生代太平洋古陆和早二叠世晚期以来欧亚大陆3个发展阶段。指出在中晚寒武世和晚奥陶世哈萨克斯坦板块靠近塔里木、中朝和华南-东南亚板块;在早古生代其余时期它接近西伯利亚板块。伊犁和托克逊-雅满苏地体是在中泥盆世之前裂解自塔里木板块,尔后在早二叠世晚期接近安加拉古陆。塔里木板块北东缘北山地区在早二叠世早期首先靠近安加拉古陆。塔里木与西伯利亚-哈萨克斯坦板块之间缝合时代大抵上和土耳其-中伊朗-冈底斯与华南-东南亚板块之间缝合时代一致。缝合事件发生在早二叠世早期,而相应的构造运动出现在早晚二叠世之交。 相似文献
17.
早古生代江南隆起的形成与剥蚀作用可以用来制约华南广西期造山作用及其动力学机制.通过对江南隆起南侧湘东南南湾地区中泥盆统跳马涧组石英砂砾岩的碎屑锆石U-Pb年代学、锆石微量元素地球化学以及全岩地球化学的分析,讨论了其物源及其大地构造意义.4件样品的270颗有效碎屑锆石U-Pb年龄谱由430~440 Ma主峰与800~1 100 Ma、1 700~2 000 Ma和2 400~2 600 Ma次峰组成.锆石CL图像、Th/U比值以及稀土元素配分图指示碎屑锆石以岩浆锆石为主,仅有少量变质锆石和热液锆石.矿物形态、组成以及成熟度指示其源区为近源,沉积于滨海环境.综合源区分析表明,湘东南中泥盆统跳马涧组石英砂砾岩的物源来自其北侧的江南隆起.江南隆起形成于广西期陆内造山作用.早古生代岩浆锆石的微量元素地球化学特征表明其为大陆型锆石,形成于大陆弧构造环境.结合区域地质特征,华南广西期造山作用是其南侧大洋俯冲作用的产物,与冈瓦纳大陆的聚合有关. 相似文献
18.
东秦岭古生代古生物区与古地理变迁 总被引:2,自引:0,他引:2
本文根据对东秦岭古生代各纪古生物区的分析,指出在北美岭褶皱带,二郎坪海槽寒武纪放射虫和微浮游植物属华南区,奥陶纪头足类,腹足类、珊瑚为华北区,早志留世珊瑚为华南区,柿树园海槽中泥盆世至二叠纪孢子主要见于华南区,干江河海槽泥盆纪珊瑚,海百合为华南区。在南秦岭褶皱带,浙川陆棚寒武纪三叶虫有华北区和华南区的分子,奥陶纪牙形石、头足类由华南区变为华北区,晚奥陶世腕足类、三叶虫、珊瑚为华北区,而早志留世笔石,晚泥盆世珊瑚,腕足类和Ting、古植物以及早石炭世珊瑚和Ting均为华南区,南湾海槽泥盆纪孢子为华南区。在此基础上探讨了东秦岭古生代古地理变迁过程。 相似文献
19.
The central–south domain of the Tibet Plateau represents an important part of the northern segment of Gondwana during the early Paleozoic. Here we present zircon U–Pb, Lu–Hf isotope, and whole–rock geochemical data from a suite of early Paleozoic magmatic rocks from the central Tibet Plateau, with a view to gain insights into the nature and geotectonic evolution of the northern margin of Gondwana. Zircon grains in four granitic rocks yielded ages of 532−496 Ma with negative εHf(t) values (−13.7 to −0.6). Zircon grains in meta–basalt and mafic gneiss yielded ages of 512 ± 5 Ma and 496 ± 6 Ma, respectively. Geochemically, the granitic rocks belong to high–K calc–alkaline and shoshonitic S–type granite suite, with the protolith derived from the partial melting of ancient crustal components. The mafic gneiss and meta–basalt geochemically resemble OIB (Oceanic Island Basalt) and E–MORB (Enriched Mid–Ocean Ridge Basalt), respectively. They were derived from low degree (∼5–10%) partial melting of an enriched mantle (garnet and spinel lherzolite) that was contaminated by upper crustal components. The parental magmas experienced orthopyroxene–dominated fractional crystallization. Sedimentological features of the Cambrian–Ordovician formations indicate that the depositional cycle transformed from marine regression to transgression leading to the formation of parallel/angular unconformities between the Cambrian and Ordovician strata. The hiatus associated with these unconformities are coupled with the peak of the early Paleozoic magmatism in Tibet Plateau, indicating a tectonic control. We conclude that the Cambrian–Ordovician magmatic suite and sedimentary rocks formed in an extensional setting, and we correlate this with the post–peak stage of the Pan–African orogeny. The post–collision setting associated with delamination, orogenic collapse or lithospheric extension along the northern margin of Gondwana, can account for the Cambrian–Ordovician magmatism and sedimentation, rather than oceanic subduction along the external margin. We thus infer a passive margin setting for the northern Gondwana during the Early Paleozoic. 相似文献
20.
云南南部及其邻区志留系对比 总被引:6,自引:0,他引:6
对云南南部墨江、绿春、金平等地志留纪地层及所含化石的分析、对比表明 ,该地区与东面的华南板块和西面的滇缅马板块存在显著差异 ,而与越南马江以西地区相似 ,因而应属于印支板块。根据广西玉林、钦州地区志留系与越南中部地层的相似性 ,及其与华南板块相应地层的差别 ,该地区可能也属印支板块 ,但后来随着冈瓦纳大陆的向北漂移和解体而分开 ,并最终与华南板块碰撞拼合。滇西保山、潞西地区的志留系与缅甸东部、泰国、马来西亚西部相似 ,应同属滇缅马板块。本文还对墨江—绿春—金平—老挝东部—越南中部一带的早古生代地层序列进行了对比 ,结果显示 ,从南到北最老的沉积盖层在形成时间上由老递新 ,这表明奥陶纪—泥盆纪期间印支板块和华南板块之间可能存在一个从东南向西北逐渐拉张的洋盆 ,在洋盆的西缘斜坡上沉积了早古生代地层 ,该洋盆在早石炭世随印支板块与华南板块的碰撞而闭合 相似文献