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1.
再论湘中南区龙潭组的时代 总被引:2,自引:0,他引:2
根据最新取得的古生物资料以及层序地层研究的成果,笔者认为湘中南区龙潭组的时代为中二叠世晚期至晚二叠世早期,龙潭组上段为晚二叠世早期,其下段为中二叠世晚期。 相似文献
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西藏羌塘盆地可分为北羌塘坳陷、中央隆起带和南羌塘坳陷3个二级构造单元。在早及中三叠世,羌塘盆地具相似的岩相古地理格局,北羌塘坳陷受可可西里-巴颜喀拉海槽的海侵作用,表现为陆表海沉积,而南羌塘坳陷和中央隆起带此时处于剥蚀环境。至晚三叠世,受班公湖-怒江洋扩张作用的影响,除中央隆起带西段继续遭受剥蚀外,羌塘盆地普遍接受沉积。南北羌塘水域虽经双湖海峡连为一体,但盆地性质发生根本性变化,构造岩相组合也明显不同。南羌塘盆地为班公湖-怒江洋北侧的扩张边缘海盆,而北羌塘则是可可西里-巴颜喀拉造山作用下的前陆盆地。羌塘盆地三叠纪岩相古地理具有“东西呈带,带中分块”的格局,这一特点是区域构造演化和基底断裂联合作用所致。 相似文献
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班公湖-怒江洋形成演化新视角:兼论西藏中部古-新特提斯转换 总被引:8,自引:7,他引:1
班公湖-怒江洋的形成演化是认识班公湖-怒江成矿带成矿地质背景的关键,近几年中国地质调查局在青藏高原部署了大量1∶50000区域地质调查工作,取得了很多重要发现。对班公湖-怒江结合带两侧关键性海陆沉积地层对比研究,认为南羌塘地块与拉萨地块晚古生代-晚三叠世地层沉积特征及岩石组合基本一致,二者在班公湖-怒江中生代洋盆形成以前是一个整体,为冈瓦纳大陆北缘被动陆缘环境。班公湖-怒江洋在早中侏罗世裂解形成,至中侏罗世趋于稳定且范围最大;向北俯冲消减作用始于中晚侏罗世,晚侏罗世-早白垩世演化为残留海,早白垩世中晚期出现短暂的裂解,致使海水重新灌入;晚白垩世班公湖-怒江洋盆进入闭合后的隆升造山阶段,发生了残留盆地迁移,形成了磨拉石建造。班公湖-怒江洋类似古加勒比海(现今墨西哥湾地区)的形成机制,并与大西洋、太平洋的形成过程关系密切。对于班公湖-怒江洋的闭合和冈底斯弧的形成,本文提出了另一种可能解释,即,新特提斯洋向北俯冲下,岩浆弧逐步南迁,在弧后形成了一系列伸展性质的弧后盆地,两者组成微陆块由北向南逐渐增生形成了现今的拉萨地体,持续向北俯冲也导致了班公湖-怒江洋最终闭合。 相似文献
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Nie Zetong Song Zhimin 《地球科学》1990,(3)
本文通过对西藏二叠系(竹蜓)类及非(竹蜓)有孔虫的研究认为,早二叠世早期(竹蜓)类以冷温型的Monodiexodina动物群为主,属冈瓦纳—特提斯生物区,冈瓦纳大陆与欧亚太陆及扬子地块的分界分别为昆仑山南坡断裂和金沙江断裂。早二叠世晚期(竹蜓)类Neoschwagerina-Polydiexodina动物群仍限于冈瓦纳北缘区,其生物区系以及扬子地块的分界与早二叠世早期相同,而冈瓦纳大陆北缘西部首先与欧亚大陆塔里木等地块接近,该动物群才越过了昆仑山北坡。晚二叠世晚期(竹蜓)类以Palaeofusulina动物群为主,与扬子地块相似属华夏—特提斯生物区,冈瓦纳与欧亚大陆的界线转为班公湖—怒江断裂,而冈底斯带与喜马拉雅带至今未见Palaeofusulina,该二带仍属冈瓦纳—特提斯生物区。 相似文献
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遵循刘宝珺院士提出的“构造控盆、盆地控相”指导思想,在系统厘定地层格架和构造单元划分基础上,确定青藏高原巨型造山带晚三叠世构造-古地理从北往南依次发育:羌塘-三江多岛海、班公湖-双湖-怒江洋、冈底斯-喜马拉雅多岛海和若干次级构造-古地理单元。班公湖-双湖-怒江洋是分隔冈瓦纳大陆和欧亚大陆的特提斯大洋,南羌塘地块是漂浮在特提斯大洋中的块体。本次重点对北羌塘前陆盆地和北喜马拉雅被动大陆边缘盆地的沉积相带展布和古地理进行了研究。造成两个盆地沉积序列及古气候差别的主要因素是构造地质事件。构造事件决定了盆地性质,盆地性质又控制了沉积相带的空间展布。北喜马拉雅盆地位于冈瓦纳构造域,晚三叠世盆地基底南浅北深,继承了古生代构造离散型被动大陆边缘沉积,印支造山作用不发育;北羌塘盆地位于泛华夏构造域,晚三叠世发育印支挤压造山作用及其前陆盆地沉积记录。盆地分析研究表明,北羌塘南部江爱达日那和热觉茶卡等地下三叠统康鲁组底部均发现灰紫色中厚层复成分砾岩、含砾粗砂岩、细砂岩组成向上变细的海侵型地层结构,沉积相为滨岸三角洲;上三叠统土门格拉群沉积相为含煤盆地边缘三角洲。从沉积相展布型式和北东向古水流方向分析,三叠纪北羌塘沉积盆地的物源主要来自羌塘中部双湖造山剥蚀区或“中央隆起带”。 相似文献
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位于拉萨地块南缘的叶巴组内首次采集到丰富的双壳类化石,共计有14个种和未定种,表明叶巴组的火山活动发生在中株罗世巴柔期,中株罗早期是新特提斯洋盆形成的重要阶段。拉萨地块上所发现的海相双壳类动物群具有东、西特提斯生物地理分区的典型分子,表明在此期间所谓的“班公湖-怒江海”未构成对拉萨地块和羌塘地块之间动物群互相沟通的地理障碍。 相似文献
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对东特提斯地区二叠-三叠纪古气候特征及其演化的系统分析表明,二叠纪-晚三叠世期间东特提斯地区分带型气候特征仍然较为清楚.二叠纪早期非暖水沉积在印度板块上的时空分布表明,现今印度板块东南边缘当时应贴近南极洲而非澳大利亚西北部.早二叠世早期非暖水沉积的北界在滇西位于昌宁-孟连带之西;在青藏高原,可能位于班公湖-丁青带.之后随着联合古大陆的整体北移,亲冈瓦纳地块群经历了由南温带到热带的古气候演化,欧亚大陆南部经历了由热带到北温带的古气候演化.各地块二叠-三叠纪期间古气候特征的演化为其古地理位置的确定提供了重要依据.二叠纪栖霞期古地理再造表明特提斯洋具多岛洋特点,二叠纪早期昌宁-孟连洋向北延入班公湖-怒江带,向南延入清迈带,大体占据南部亚热带,宽约10°古纬距. 相似文献
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Permian Fusuline Fauna from the Lower Part of the Lugu Formation in the Central Qiangtang Block and its Geological Implications 总被引:2,自引:0,他引:2
A Kubergandian (Kungurian) fusuline fauna from the lower part of the Lugu Formation in the Cuozheqiangma area,central Qiangtang Block is described.This fusuline fauna belongs to the Southern Transitional Zone in palaeobiogeography,and is characterised by the presence of the distinctive bi-temperate genus Monodiexodina and many genera common in lower latitude Tethyan areas such as Parafusulina and Pseudodoliolina.The occurrence of Monodiexodina in the fauna confirms that the seamount-type carbonates of the Lugu Formation did not originate from the Palaeotethys Ocean,but rather from a branch of the Neotethys Ocean after the rifting of the Qiangtang Block from the Tethys Himalaya area in the Artinskian. 相似文献
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The location of the Palaeo-tethys suture in Tibet has been in great dispute for past two decades. The Longmucuo-Shuanghu suture has long been considered as the Palaeo-tethys in Tibet. Restudy of the Carboniferous and Permian sequences in the north and south of this suture reveal that: (1) the Carboniferous and Permian se-quence of the North Qiangtang Block is characterized by containing compound corals and intact fusulinids zones from Moscovian Fusulinella, Fusulina to Changhsingian Palaeofusulina zones; (2) the Early Permian of the South Qiangtang Block is dominated by diamictites and the Middle Permian carbonates found there may deposit on the oceanic seamount. 相似文献
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西藏羌塘盆地白垩纪中期构造事件的磷灰石裂变径迹证据 总被引:4,自引:1,他引:3
拉萨与羌塘地块于白垩纪中期的碰撞造山对羌塘原型盆地的热体制和构造演化有着重要影响.运用磷灰石裂变径迹方法,对羌塘盆地隆鄂尼夏里组和托纳木雪山组砂岩分析表明,裂变径迹年龄集中在120~ 80Ma之间,表明在白垩纪中期,羌塘盆地普遍发生了一次构造抬升事件,该期构造事件的年龄与盆地内早白垩世的岩浆热事件、主要构造变形作用发生在晚白垩世以及雪山组和阿布山组角度不整合的时代(125~75Ma)较一致,是拉萨与羌塘地块碰撞造山事件的记录.热历史模拟表明,白垩纪中期构造事件对羌塘盆地南部和北部的热演化历史有着差异影响,羌塘盆地南部降温速率相对不大,抬升剥蚀厚度约1500m,而北部古地温迅速降温到近地表温度,抬升剥蚀厚度近4000m.这种差异抬升剥蚀可能与班公湖-怒江洋壳向南俯冲使得因拉萨地块构造负载而导致羌塘地块的挠曲有关. 相似文献
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《International Geology Review》2012,54(2):228-245
AbstractThis article reports the depositional environment and provenance for the Tianquanshan Formation in the Longmuco–Shuanghu–Lancangjiang suture zone, and uses these to better understand the tectonic evolution of this region. Zircons in the andesite of the Tianquanshan Formation yielded concordia ages of 246, 247, and 254 Ma, indicating that the Tianquanshan Formation formed during the late Permian–Early Triassic. The Tianquanshan Formation consists of flysch and ocean island rock assemblages, indicating that the Longmuco–Shuanghu–Lancangjiang Palaeo-Tethys Ocean continued to exist as a mature ocean in the late Permian–Early Triassic. The detrital zircons in the greywackes of the Tianquanshan Formation yielded peak ages of 470–620, 710–830, 910–1080, 1450–1660, and 2400–2650 Ma, indicating the provenance of the Tianquanshan Formation was either Indian Gondwana or terranes that have an affinity with Indian Gondwana in the Tibetan Plateau (i.e. the Southern Qiangtang, Lhasa, and Himalayan terranes). The Ordovician quartzites, Carboniferous sandstones, Carboniferous–Permian diamictites, and the Upper Permian–Lower Triassic greywackes in the Southern Qiangtang, Lhasa, and Himalayan terranes all contain detrital zircons with youngest ages of ca. 470 Ma, indicating their source areas have been in a stable tectonic environment since the Ordovician, and this inference is supported by the continuous deposition in a littoral–neritic passive margin in these regions from the Ordovician to the lower Permian. Combining the present results with regional geological data, we infer that the Southern Qiangtang, Lhasa, and Himalayan terranes were all in a stable passive continental margin along the northern part of Indian Gondwana during the long period from the Ordovician to the early Permian. At early Permian, because of the opening of the Neo-Tethys Ocean, the tectonic framework of this region underwent a marked change to a rifting and active environment. 相似文献
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Early Cretaceous Tectonics and Evolution of the Tibetan Plateau 总被引:1,自引:1,他引:0
Selected geological data on Early Cretaceous strata, structures, magmatic plutons and volcanic rocks from the Kunlun to Himalaya Mountains reveal a new view of the Early Cretaceous paleo-tectonics and the related geodynamic movement of the Tibetan Plateau. Two major paleo-oceans, the Mid-Tethys Ocean between the Qiangtang and Lhasa blocks, and the Neo-Tethys Ocean between the Lhasa and Himalayan blocks, existed in the Tibetan region in the Early Cretaceous. The Himalayan Marginal and South Lhasa Seas formed in the southern and northern margins of the Neo-Tethys Ocean, the Central Tibet Sea and the Qiangtang Marginal Sea formed in the southern and northern margins of the Mid-Tethys Ocean, respectively. An arm of the sea extended into the southwestern Tarim basin in the Early Cretaceous. Early Cretaceous intensive thrusting, magmatic emplacement and volcanic eruptions occurred in the central and northern Lhasa Block, while strike-slip formed along the Hoh-Xil and South Kunlun Faults in the northern Tibetan region. Early Cretaceous tectonics together with magmatic K2O geochemistry indicate an Early Cretaceous southward subduction of the Mid-Tethys Oceanic Plate along the Bangoin-Nujiang Suture which was thrust ~87 km southward during the Late Cretaceous-Early Cenozoic. No intensive thrust and magmatic emplacement occurred in the Early Cretaceous in the Himalayan and southern Lhasa Blocks, indicating that the spreading Neo-Tethys Oceanic Plate had not been subducted in the Early Cretaceous. To the north, terrestrial basins of red-beds formed in the Hoh-Xil, Kunlun, Qilian and the northeastern Tarim blocks in Early Cretaceous, and the Qiangtang Marginal Sea disappeared after the Qiangtang Block uplifted in the late Early Cretaceous. 相似文献
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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
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西藏雅鲁藏布江缝合带(YZSZ)和班公湖-怒江缝合带(BNSZ)蛇绿岩代表了新特提斯洋壳和岩石圈地幔残余,是我国铬铁矿和蛇绿岩型金刚石的重要原产地,目前这两条蛇绿岩带的成因和相互关系还存在着争论。本文总结了YZSZ、BNSZ、狮泉河-纳木错蛇绿混杂岩带(SNMZ)和松多缝合带蛇绿岩的时空分布、组成和构造背景,归纳了拉萨地块晚古生以来的岩浆岩分布,获得以下主要认识:(1)Panjal地幔柱活动可能促使怒江洋和雅江西洋在早二叠世空谷期(283~272Ma)打开;(2)雅江东洋由于松多洋的南向俯冲在晚三叠世打开,与雅江西洋以萨嘎-措勤为界,并形成冈底斯东部245~200Ma岩浆热事件;(3)~140Ma班怒洋闭合以及南羌塘与北拉萨地块碰撞,导致雅江洋扩张速率加快而引发了北向拉萨地块的平板俯冲,进而导致班怒洋的再次裂解形成133~104Ma"红海型"小洋盆;(4)YZSZ缝合带西段南带蛇绿岩为北带的逆冲推覆体;(5)BNSZ和SNMZ蛇绿岩隶属于一个洋盆,后者代表了班怒洋成熟洋盆扩张脊的残余。 相似文献
18.
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
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
19.
Tong-Tong Huang Jian-Lin Chen Jian-bin Wu Yun-Chuan Zeng 《International Geology Review》2017,59(2):166-184
The subduction polarity and related arc–magmatic evolutional history of the Bangong–Nujiang Ocean, which separated the South Qiangtang terrane to the north from the North Lhasa terrane to the south during the Mesozoic, remain debated. This study tries to reconstruct the subduction and evolution of the Bangong–Nujiang Ocean on the basis of U–Pb and Hf isotopic analyses of detrital zircons in samples from sedimentary rocks of the middle-western section of the Bangong–Nujiang suture zone in Gerze County, central Tibet. The Middle Jurassic Muggargangri Group in the Bangong–Nujiang suture zone was deposited in a deep-sea basin setting on an active continental margin. The Late Jurassic strata, such as the Sewa Formation, are widely distributed in the South Qiangtang terrane and represent deposition on a shelf. The Early Cretaceous Shamuluo Formation in the Bangong–Nujiang suture zone unconformably overlies the Muggargangri Group and was probably deposited in a residual marine basin setting. The detrital zircons of the Muggargangri Group contain seven U–Pb age populations: 2.6–2.4 Ga, 1.95–1.75 Ga, 950–900 Ma, 850–800 Ma, 650–550 Ma, 480–420 Ma, and 350–250 Ma, which is similar to the age populations in sedimentary rocks of the South Qiangtang terrane. In addition, the age spectra of the Shamuluo Formation are similar to those of the Muggargangri Group, indicating that both had a northern terrane provenance, which is conformed by the north-to-south palaeocurrent. This provenance indicates northward subduction of the Bangong–Nujiang oceanic crust. In contrast, two samples from the Sewa Formation yield variable age distributions: the lower sample has age populations similar to those of the South Qiangtang terrane, whereas the upper possesses only one age cluster with a peak at ca. 156 Ma. Moreover, the majority of the late Mesozoic detrital zircons are characterized by weakly positive εHf(t) values that are similar to those of magmatic zircons from arc magmatic rocks in the South Qiangtang terrane. The findings, together with information from the record of magmatism, indicate that the earliest prevalent arc magmatism occurred during the Early Jurassic (ca. 185 Ma) and that the principal arc–magmatic stage occurred during the Middle–Late Jurassic (ca. 170–150 Ma). The magmatic gap and scarcity of detrital zircons at ca. 140–130 Ma likely indicate collision between the Qiangtang and Lhasa terranes. The late Early Cretaceous (ca. 125–100 Ma) magmatism on both sides of the Bangong–Nujiang suture zone was probably related to slab break-off or lithospheric delamination after closure of the Bangong–Nujiang Ocean. 相似文献