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西藏南部早第三纪钙质超微化石及东特提斯在西藏境内的封闭时限 总被引:14,自引:0,他引:14
研究了西藏南部定日地区曲密巴剖面早第三纪遮普惹组上页岩段的钙质超微化石 ,自下而上划分出 3个超微化石组合 :N annotetrina fulgens-Chiasmolithusgigas组合 ;Discoaster bifax-Chiasmolithussolitus组合及 Sphenolithuspseudoradians-Reticulofenestra bisecta组合 ,确定了上述3组合可与 Martini( 1 971 )超微化石分带的 NP1 5、NP1 6及 NP1 7带对比。还确认了第三超微化石组合的层位是西藏地区海相第三纪目前已知的最高层位 ,它的时代应为中始新世晚期 ,即属 Bartonian期。根据超微化石属种的时限分布的分析 ,东特提斯在西藏境内的封闭时间大约在3 8Ma左右 ,即至该时期 ,海水完全退出青藏高原 ,印度板块和欧亚板块完全拼合 ,青藏高原开始大幅度的隆升。 相似文献
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Randomisation tests on boulder weathering data distinguish moraines of four different ages in the Rongbuk Valley, all deposited by valley glaciers flowing northward into Tibet from the Himalaya. Lichenometry utilising subgenus Rhizocarpon distinguishes two groups of moraines, those <100 yr old and those older than several thousand years. The degree of soil development has a similar, limited utility in relative-age dating these moraines. The radiocarbon ages of calcium carbonate coatings in the lower horizons of moraine soils provide minimum-limiting ages of 1900 yr BP for the penultimate advance of the Rongbuk glacier (Samdopo moraine) and 9500 yr BP for the Rongbuk moraine, the moraine suggested by previous workers to represent the last glacial maximum. Equilibrium-line depression associated with the Rongbuk moraine probably was slight, <200 m. The small magnitude of this depression relative to glaciers in other mountain ranges could relate to a weakening of the monsoon in full glacial times, recent tectonic uplift, and/or to the insensitivity of these high-altitude glaciers to lowering temperatures in the rain shadow of Mount Everest. 相似文献
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Western Tibet, between the Karakorum fault and the Gozha–Longmu Co fault system, is mostly internally drained and has a 1.5–2 km amplitude relief with km-large valleys. We investigate the origin of this peculiar morphology by combining a topography analysis and a study of the Cenozoic sedimentation in this area. Cenozoic continental strata correspond to a proximal, detrital fan deposition, and uncomformably rest on a palaeorelief similar to the modern one. Zircon U–Pb dating from trachytic flows interbedded within the Cenozoic continental sediments indicates that detrital sedimentation occurred at least between ca 24 and 20 Ma in the Shiquanhe basin, while K/Ar ages suggest it may have started since ~ 37 Ma in the Zapug basin. The distribution of continental deposits shows that present-day morphology features, including km-large, 1500 m-deep valleys, were already formed by Early Miocene times. We suggest that today's internally drained western Tibet was externally drained, at least during late Miocene, contemporaneously with early motion along the Karakorum Fault. Detailed study of the present day river network is compatible with a dextral offset on the Karakorum Fault of 250 km at a rate of ~ 10 ± 1 mm/yr. Displacement along the Karakorum fault possibly induced the shift from external to an internal drainage system, by damming of the Bangong Co ~ 4 Ma ago, leading to the isolation and preservation of the western Tibet relief. 相似文献
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New major and trace elemental, Sr–Nd–Pb isotope, and zircon U–Pb geochronological and Hf–O isotope data of post-collisional potassic and ultrapotassic volcanic rocks (PVRs and UPVs, respectively) along with geochemical data of PVRs, UPVs, and Mg-rich potassic rocks (MPRs) in the literature are used to constrain their mantle source and genesis. The PVRs, UPVs, and MPRs share similar geochemical features but with some discrepancies, suggesting that they were derived from subcontinental lithospheric mantle (SCLM) with isotopic heterogeneity resulting from the varying contributions of subducted Indian lower crust into the mantle source (ca. 6–20%, ca. 8–30%, and ca. 9–30%, respectively). The zircon Hf–O isotopic compositions of these rocks can be classified into two groups, including Group I rocks with high δ18O (6.7–11.3‰), low εHf(t) (− 17.0 to − 12.0), and old Hf crustal model ages (1.87–2.19 Ga) that indicate an ancient SCLM source, and Group II rocks with δ18O values of 6.8–10.7‰, εHf(t) values of − 11.8 to − 6.3, and younger Hf crustal model ages (1.50–1.86 Ga). The negative correlation defined by δ18O and εHf(t) of Group II samples suggests a two-component mixing between mantle- and crust-derived melts, in which the latter would be the subducted Indian lower crust as indicated by the similar negative εHf(t) values between Group II samples (− 11.8 to − 6.3) and the High Himalayan gneiss (− 14.2 to + 0.3). Thus we propose two enrichment events to account for the Hf–O isotopic compositions of the PVRs and UPVs/MPRs: the first involves the enrichment of the overlying SCLM that was metasomatized by fluids derived from dehydration of the subducted Indian lower crust, and the second invokes the enrichment of the overlying SCLM metasomatized by melts of the already dehydrated different proportions of the Indian lower crust. We argue that break-off of the northwards subducted Indian Plate in the early Miocene caused the asthenospheric upwelling under the Indian plate through slab window, resulting in varying degrees of partial melting of the overlying metasomatized heterogeneous SCLM to produce the primitive magmas of the PVRs, UPVs, and MPRs in an extensional setting. These observations and interpretations imply that the Indian lower crust was subducted beneath the Lhasa terrane in the Early–Middle Miocene. 相似文献
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青藏高原是新生代以来由于印度板块与欧亚板块碰撞而迅速隆起,平均海拔超过4000 m的高原,是研究碰撞过程和形成演化的理想窗口。有关青藏高原的碰撞过程及印度板块岩石圈北缘界线,至今仍然存在较大争议,这可能主要是由于不同研究方法获得认识的差异性和局限性所导致。基于此,本文利用前人深部结构资料,讨论了高原岩石圈的壳幔构造及物质组成等,并从新的地质视角讨论了班怒带的大地构造属性。通过梳理前人的深部结构资料,认为青藏高原的壳幔岩石圈结构较为复杂,如高原内部岩石圈厚度显著大于周缘地区,中下地壳及上地幔广泛分布着低速高导层,这些特殊的地质地球物理结构是印亚板块碰撞的结果。此外,本文进一步对比分析了班怒带的地质与地球物理结构,揭示该构造带两侧存在显著的差异,认为其是印度岩石圈的北缘,这对于认识青藏高原的形成演化具有重要的意义。 相似文献
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《Comptes Rendus Geoscience》2008,340(2-3):180-189
The Triassic fold belt of North Tibet is mainly composed, from west to east, of the Bayan Har, Songpan–Garzê, and Yidun (or Litang–Batang) terranes. The Indosinian orogeny results from interactions between the South China, North China and Qiangtang (North Tibet) blocks during the closure of the Palaeotethys. A synthesis of the tectonic and geochronological data available on this belt is presented and a new geodynamic model of its formation is proposed. At the end of the Permian, a synchronous activity along three subduction zones, Kunlun–Anyemaqen to the north, Jinsha to the south and Yushu–Batang to the east, induced the growth of wide accretionary orogens until the end of the Triassic period. The onset of subduction in Tibet is contemporaneous with Indosinian tectonism in Indochina (pre-Norian). However, the main tectonic events that lead to the closure of the Tethysian basin and the subsequent building of the Triassic belts are younger (220–200 Ma). 相似文献
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藏南错那洞淡色花岗岩年代学研究及其对藏南拆离系活动时间的限定 总被引:6,自引:3,他引:3
北喜马拉雅片麻岩穹窿带(NHGD)内保存了大陆碰撞后青藏高原中下地壳的构造变形、高级变质、陆壳深熔作用等重要信息,是研究喜马拉雅造山带的深部岩浆作用和构造变形之间的耦合关系、深部岩浆活动乃至青藏高原隆升历史等大陆动力学过程的关键部位。本文对藏南错那洞穹窿内淡色花岗岩进行锆石LA MC-ICP-MS U-Pb、白云母~(40)Ar/~(39)Ar年代学和岩石地球化学分析。锆石U-Pb定年和白云母~(40)Ar/~(39)Ar测年结果表明错那洞淡色花岗岩形成于19.5±0.3Ma~19.7±0.7Ma,冷却年龄为15Ma。岩石地球化学特征显示该花岗岩具有明显的Eu负异常,稀土配分模式和微量元素蛛网图与以Manaslu为代表的高喜马拉雅淡色花岗岩一致,而不同于具有加厚地壳的埃达克岩的特征的北喜马拉雅淡色花岗岩,其形成于与南北向拆离相关的伸展环境。 相似文献
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青藏高原岩石圈演化的记录:藏北超钾质及钠质火山岩的岩石学与地球化学特征 总被引:56,自引:12,他引:44
藏北鱼鳞山超钾质火山岩为一中等规模的熔岩被, 可分为三期。前两期主要为霞石黝方白榴石响岩、霞石白榴斑岩等, 后期主要为方钠石霓石粗面岩、霓霞粗面岩等。时代为18~30 Ma。本区超钾质岩浆 Si O2 强烈不饱和、强碱性、高度富集 L R E E及 L I L E、放射成因 Sr、 Pb 及非放射成因 Nd 同位素 (86 Sr/87 Sr= 0708766~0709162, 206 Pb/204 Pb= 18882888~ 19104751, 207 Pb/204 Pb= 15642037 ~ 15828458, 208 Pb/204 Pb= 39138921 ~ 39686835 及143 Nd/144 Nd= 0512116 ~0512342),其上述特征指示岩浆源区为受到地壳物质强烈交代的富集 E M I I型地幔。藏北拉嘎拉钠质碱性橄榄玄武岩为高原面上的剥蚀残丘, 时代为60 Ma。其岩石学、 R E E、微量元素及 Sr Nd Pb 同位素指示了岩浆源区为受到洋壳俯冲物质交代的轻度富集地幔。本研究结果指示, 羌塘高原南部富集地幔的形成可能是受到印度板块俯冲的影响。 相似文献
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Summary Mineralogical investigations of rock samples from the Transhimalaya and Tibetan Himalaya allow the conclusion that during the last glaciations in this area there was long distance glacial transport. The samples from the Mt. Everest group, the highest region of the continental crust, provide an account of the petrological data collected from this area. They depict a juxtaposition of sedimentary series and granitic intrusive bodies and also extreme tectonic action deep into their cystalline structure. 相似文献
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青藏高原东南部出露有大量近东西向展布的(超)镁铁质岩墙,锆石U?Pb年龄聚集在145~130 Ma之间。矿物学及岩石学结果显示:哲古错地区的亚碱性超镁铁苦橄质岩石源于150~180 km深处, 5~6 GPa下石榴石二辉橄榄岩地幔高比率的部分熔融; 碱性超镁铁质岩石源于石榴石-尖晶石二辉橄榄岩转换带,是低比率部分熔融的产物; 镁铁质岩石的岩浆在演化过程中遭受了低压下结晶分离作用的改造,不能代表原始岩浆的成份。藏东南(超)镁铁质岩石是不同深度地幔物质不同比率部分熔融的产物,亚碱性超镁铁苦橄质岩墙的出现指示了晚侏罗-早白垩印度板块北缘存在的高比率部分熔融的岩浆活动事件,暗示了地幔柱的存在和影响。 相似文献
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ZOU Guangfu PAN Zhongxi ZHUANG Zhonghai ZHU Tongxing LI Jianzhong FENG Xintao 《《地质学报》英文版》2013,87(2):517-527
This paper conducts systematic test research on the 2920 paleomagnetic directional samples taken from Ordovician-Paleogene sedimentary formation in the north slope of Qomolangma in south of Tibet and obtains the primary remanent magnetization component and counts the new data of paleomagnetism the times. Based on the characteristic remanent magnetization component, it calculates the geomagnetic pole position and latitude value of Himalaya block in Ordovician-Paleogene. According to the new data of paleomagnetism, it draws the palaeomagnetic polar wander curve and palaeolatitude change curve of the north slope of Qomolangma in Ordovician-Paleogene. It also makes a preliminary discussion to the structure evolution history and relative movement of Himalaya bloc. The research results show that many clockwise rotation movements had occurred to the Himalaya block in northern slope of Qomolangmain the process of northward drifting in the phanerozoic eon. In Ordovician-late Cretaceous, there the movement of about 20.0° clockwise rotation occurred in the process of northward drifting. However, 0.4° counterclockwise rotation occurred from the end of late Devonian epoch to the beginning of early carboniferous epoch; 6.0° and 8.0° counterclockwise rotation occurred in carboniferous period and early Triassic epoch respectively, which might be related with the tension crack of continental rift valley from late Devonian period to the beginning of early carboniferous epoch, carboniferous period and early Triassic epoch. From the Eocene epoch to Pliocene epoch, the Himalaya block generated about 28.0° clockwise while drifting northward with a relatively rapid speed. This was the result that since the Eocene epoch, due to the continuous expansion of mid-ocean ridge of the India Ocean, the neo-Tethys with the Yarlung Zangbo River as the main ocean basin closed to form orogenic movement and the strong continent-continent collision orogenic movement of the east and west Himalayas generated clockwise movement in the mid-Himalaya area. According to the calculation of palaeolatitude data, the Himalaya continent-continent collusion orogenic movement since the Eocene epoch caused the crustal structure in Indian Plate-Himalaya folded structural belt-Lhasa block to shorten by at least 1000 km. The systematic research on the paleomagnetism of Qomolangma area in the phanerozoic eon provides a scientific basis to further research the evolution of Gondwanaland, formation and extinction history of paleo-Tethys Ocean and uplift mechanism of the Qinghai-Tibet Plateau. 相似文献
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As part of the Sino-French earth science programme in Tibet, magnetotelluric and geomagnetic soundings were carried out in
the southwestern part of Tibet.
Eight magnetotelluric sounding sites and nineteen geomagnetic stations were occupied along roughly north-south profiles. The
magnetotelluric profile runs from Lhozag to the south of Yangbajain to the north. The geomagnetic profile runs from Lang Kartse
to Gulu.
These experiments indicate a conductive layer at about 25 km in depth. This layer corresponds to the isotherm 1100°C. Shallow
conductive structures related to the presence of significant partial melting were evidenced to the south of the Zangbo suture.
A conductive structure was also evidenced at about 15 km in depth below the Nyainquentanglha range. This structure may correspond
to partial melting due to the presence of fluids at the dipping plane between two overthrusting crustal blocks. 相似文献
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The Zedang and Luobusa ophiolites are located in the eastern section of the Yalung Zangbo ophiolite belt,and they share similar geological tectonic setting and age.Thus,an understanding of their origins is very important for discussion of the evolution of the Eastern Tethys Ocean.There is no complete ophiolite assemblage in the Zedang ophiolite.The Zedang ophiolite is mainly composed of mantle peridotite and a suite of volcanic rocks as well as siliceous rocks,with some blocks of olivinepyroxenite.The mantle peridotite mainly consists of Cpx-harzburgite,harzburgite,some lherzolite,and some dunite.A suite of volcanic rocks is mainly composed of caic-aikaline pyroclastic rocks and secondly of tholeiitic pillow lavas,basaltic andesites,and some boninitic rocks with a lower TiO2 content (TiO2 < 0.6%).The pyroclastic rocks have a LREE-enriched REE pattern and a LILE-enriched (compared to HFSE) spider diagram,demonstrating an island-arc origin.The tholeiitic volcanic rock has a LREE-depleted REE pattern and a LILE-depleted (compared to HFSE) spider diagram,indicative of an origin from MORB.The boninitic rock was generated from fore-arc extension.The Luobusa ophiolite consists of mantle peridotite and mafic-ultramaflc cumulate units,without dike swarms and volcanic rocks.The mantle peridotite mainly consists of dunite,harzburgite with low-Opx (Opx < 25%),and harzburgite (Opx > 25%),which can be divided into two facies belts.The upper is a dunite-harzburgite (Opx < 25%) belt,containing many dunite lenses and a large-scale chromite deposit with high Cr203; the lower is a harzburgite (Opx >25%) belt with small amounts of dunite and lherzolite.The Luobusa mantle peridotite exhibits a distinctive vertical zonation of partial melting with high melting in the upper unit and low melting in the lower.Many mantle peridotites are highly depleted,with a characteristic U-shaped REE pattern peculiar to fore-arc peridotite.The Luobusa cumulates are composed of wehrlite and olivine-pyroxenite,of the P-P-G ophiolite series.This study indicates that the Luobusa ophiolite was formed in a fore-arc basin environment on the basis of the occurrence of highly depleted mantle peridotite,a high-Cr2O3 chromite deposit,and cumulates of the P-P-G ophiolite series.We conclude that the evolution of the Eastern Tethys Ocean involved three stages:the initial ocean stage (formation of MORB volcanic rock and dikes),the forearc extension stage (formation of high-Cr203 chromite deposits and P-P-G cumulates),and the islandarc stage (formation of caic-alkaline pyroclastic rocks). 相似文献
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Georg Miehe Dr. 《GeoJournal》1988,17(4):635-648
Along with four vegetation profiles taken in 1984 in S Tibet climatically induced regressive plant successions were observed. Recently, frost heaving-adapted plant communities of the free gelifluction belt have been descending toward the alpine belt. The hypso-zonal cyperaceae turfs of the alpine belt have been exfoliated by the Himalaya föhn, and the alpine steppe communities have been advancing for an unknown period of time. The following hypothesis for this is given: The turfs must be interpreted as relics formed under wetter climatic conditions before the start of the Himalaya föhn and the related Indian summer monsoon. It is concluded that this Kobresia pygmaea age occurred just after the deglaciation of the Tibetan plateau and before the start of the Indian summer monsoon. 相似文献
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西藏第三纪有孔虫生物地层及地理环境 总被引:17,自引:2,他引:15
西藏南部海相第三系自下而上划分为:基堵拉组、宗浦组和遮普惹组。基堵拉组的归属直接关系到白垩——第三系的界线问题。以往在证据不充分的情况下将基堵拉组归于白垩系。本次工作在该组中找到了具时代意义的化石,有双壳类、介形虫、有孔虫等。通过化石群的研究确定了基堵拉组属于古新世丹宁早期。白垩—第三系界线应位于宗山组与基堵拉组之间。通过基堵拉组的横向对比得出了该组在空间上穿时的结论。浮游有孔虫动物群的发现确定了本区最高海相层为遮普惹组上段,时代属于始新世晚期。 西藏第三纪有孔虫类型丰富。据动物群的古生态研究得出了不同时代的有孔虫生物相:丹宁期为Rotalia生物相和Textularia生物相;朗德期为Miscellanea生物相和Ranikotbalia生物相;伊普尔期至路坦丁期包括Orbitolites生物相、Assilina生物相及冈底斯有孔虫生物相;普里亚波期以Globigerina生物相为特征。据有孔虫生物相的特征及氧碳稳定同位素的测试结果综合得出了西藏南部第三纪包括两次海侵旋回,即古新世和始新世旋回。二者又分别包括两回次一级的旋回,即古新世的丹宁期旋回和朗德期旋回;始新世的伊普尔期至路坦丁期旋回和普里亚波期旋回。 相似文献
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西藏易贡大滑坡成因探讨 总被引:2,自引:0,他引:2
2000年4月9日, 西藏林芝地区波密县易贡藏布札木弄沟发生了体积超过3×108 m3的特大规模滑坡, 这是该沟100年(1900—2000年)来发生的第2次大规模滑坡.在卫星遥感影像分析基础上, 结合地质、气象、地震等资料, 对札木弄沟100年内2次发生特大规模滑坡的原因进行了分析, 表明这2次滑坡是地质构造、地层岩性、新构造运动、水文和气象因素共同作用的结果.分析结果还显示, 札木弄沟已进入下一个物质与能量积累过程, 在适当的外部条件作用下, 有可能再次发生滑坡. 相似文献