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1.
东巧蛇绿岩位于班公湖—怒江缝合带中段,根据地理位置特征并以强玛镇为中心将东巧岩体划分为东西两个岩体。其中西岩体相对面积较大,由地幔橄榄岩、枕状玄武岩、辉长辉绿岩等组成;而东岩体面积较小,仅含地幔橄榄岩部分,各个不同单元之间呈断层接触关系。对东巧地幔橄榄岩开展岩石学、矿物学及地球化学研究发现:(1)东巧地幔橄榄岩以方辉橄榄岩为主,纯橄岩所占比例较小,约15%。豆荚状铬铁矿主要呈条带浸染状赋存在厚层且延伸较远的纯橄岩中。(2)东巧地幔橄榄岩中单斜辉石含量小于3%,矿物地球化学和全岩地球化学特征显示其来源于尖晶石相地幔源区的部分熔融,且部分熔融程度较高,估算在22%~28%,高于深海地幔橄榄岩的部分熔融程度(10%~22%)。(3)东巧地幔橄榄岩中的副矿物铬尖晶石Cr#值较高大于60,全岩具有U型球粒陨石标准化稀土元素配分模式,同时Rb、U、Zr和Sr相对富集,Hf和Nb相对亏损。全岩的地球化学特征指示了俯冲带之上的残余地幔与流体/熔体发生了反应,致使轻稀土元素以及部分微量元素选择性富集。综合东巧地幔橄榄岩的矿物化学组成成分以及全岩的地球化学特征,认为东巧地幔橄榄岩形成于大洋中脊的扩张环境中,后受到洋内俯冲作用的影响,导致俯冲带之上高度部分熔融的地幔橄榄岩与流体/熔体发生相互作用。 相似文献
2.
THE CHARACTERISTICS OF REMOTE SENSING TECTONICS IN QIANGTANG-CHANGDU MASSIF, QINGHAI-TIBET PLATEAU 相似文献
3.
东巧蛇绿岩出露于班公湖-怒江缝合带中段,是蛇绿岩组合单元出露较完整的地区。微量(稀土)元素分析结果表明,蛇绿岩中的玄武岩具有轻稀土元素(LREE)显著富集的右倾稀土元素配分模式。(La/Yb)N=7.05~12.02,Th、Nb、Ta、Zr和Hf略具有正异常的微量元素组成特征,属于典型的洋岛玄武岩(OIB),与洋中脊玄武岩(MORB)和板块汇聚环境下的岛弧玄武岩(IAB)存在明显差异。通过对其构造环境的判别,并结合蛇绿岩与相邻地质体的关系分析,认为东巧蛇绿岩中的玄武岩形成于大洋板内岩石圈上隆减压的洋岛环境,代表班公湖-怒江洋盆形成和发展阶段洋岛环境的大洋岩石圈残片。 相似文献
4.
本文采用蚀源区判别图解QFL和QpLsLv、微量元素图解Th -Co -Zr/10、常量元素图解K2O/Na2O -SiO2 和野外地质实测剖面等方法 ,对比如、措勤地体的构造演化进行了分析。发现并证实了在T3-J1 以前比如地体位于措勤地体的北部 :J2 -3 时随着班—恕缝合带的拉张 ,比如地体开始右旋向东滑动 :一直延续到J3-K1 时 ,班—怒缝合带闭合 ,比如地体才就位于目前位置。最后应用1/ZTR指数推测了比如地体在J2 -3 时滑移点的大致位置 (E90°49,N31°34)。 相似文献
5.
青藏高原南部雅鲁藏布江蛇绿岩带的时空分布特征及地质意义 总被引:6,自引:0,他引:6
雅鲁藏布江缝合带是青藏高原上重要的缝合带之一,位于青藏高原南部,蛇绿岩是该带的主体。雅鲁藏布江缝合带按蛇绿岩的出露规模、岩石层序以及侵位时间,大致可以分为东段、中段和西段。在蛇绿岩出露规模上存在显著差异,东段规模较小,中段次之,西段最大,并且在西段分成两支蛇绿岩带;蛇绿岩岩石层序出露比较齐全的是中段日喀则和东段罗布莎,其他地方的蛇绿岩均被肢解,不能组成完整的蛇绿岩岩石剖面;在蛇绿岩的形成和侵位时间上,也有着不同的特点,东段和西段集中形成于晚侏罗世—早白垩世,而中段形成时间较早,时代从中三叠世一直持续到早白垩世,主要集中形成于晚侏罗世—早白垩世。笔者系统研究雅鲁藏布江缝合带蛇绿岩在东西方向上所表现出来的差异性,对更全面深刻地了解新特提斯洋的产生、俯冲及其消亡过程和演化历史具有重要意义。 相似文献
6.
AbstractThis study aims at unravel the geotectonic evolution of northern Greece prior to the already established Tertiary clockwise rotation. Therefore, Mesozoie sediments, Early Mesozoie ophiolites and Carboniferous granites were sampled. While the metamorphosed and/or too weakly magnetized limestones had to be rejected, the gabbros and serpentinites of the 80 km long Chalkidiki belt (40.4°N, 23.3”E), and the granites of the northern Pelagonian zone (40.8°N, 21.2°E) have yielded similar results interpretable in terms of geoleetonies. In both areas the demagnetizing process has revealed a poh phased magnetic evolution.The oldest magnetizations, labelled M (D=311°, I=20°, a95, = 15°; VGP: 37°N, 272.5°, for the ophiolites; D=320.5°, I = 26°, a95 =11°; VGP : 46°N, 264.5”E, for the granites) are interpreted as overprints acquired in Late Jurassic-Cretaceous times. The younger magnetizations, called C2 (D = 66°, I = 28°, a95 = 9°; VGP : 28°N, 117°E, in the ophiolites ; D=64°, I = 2° a95, = 11°; VCP : 20°N, I28°E, in the granites) are Tertiary overprints. Northeasterly C’ directions with negative inclinations (and conversely) are considered as overprints empiaceli prior to the Ca magnetizations ; they are interpreted as due to a barkthrusting of the ophiolilic belt of Chalkidiki and of the N. Pelagonian granitic belt, during the Early - Middle Tertiary convergence phase. The large deviation from the M to the C2 directions, also observed by other authors in Mesozoic volcanics and sediments, results from a counterclockwise rotation of the Hellenides, probably in the Late Cretaceous as it is the case for the counterclockwise rotations of the western Mediterranean microplates. The deviation from the C2 to the present field direction is due to a clockwise rotation of all Hellenic zones, probably in several phases. 相似文献
7.
QIANGTANG MASSIF CRUST DEFORMATION FEATURES, DIFFERENCE AND ITS GENETIC MECHANISM STUDY 相似文献
8.
9.
STUDY ON THE ISOTOPIC CHRONOLOGY AND THE TECTONIC SIGNIFICANCE OF DUGUER GRANITIC GNEISS IN CENTRAL QIANGTANG, TIBET 相似文献
10.
Jacques Belliere 《Geodinamica Acta》2013,26(1):13-16
AbstractThree generations of mylonites occur in the Mont Blanc Massif :— the first one has produced mylonitic schists trending N20°E, of regional extension; the late Variscan Mont Blanc granite intruded these mylonites;— the second one has affected large areas in the Mont Blanc granite, with the same N20°E direction;— the third one is located along rather narrow bands N45°E, in the granite as well as in the older mylonitic schists.All theses mylonites have been generated under (Bi) - greenschist facies conditions. They exhibit steeply plunging schistosity and lineation. They are all ante-Alpine; paradoxically, Alpine structures within the massif do not exhibit a striking appearence. 相似文献
11.
《International Geology Review》2012,54(9):797-804
Paleozoic sequences are defined for the northern and southern Qiangtang by linking field observations in the Gaize Province to the known Paleozoic record in neighboring areas. The pre-Devonian Gemuri Group of earlier authors is divided and the use of that term is no longer recommended. The upper Paleozoic rock assemblages, geological structures, and biota of the southern Qiangtang are of Gondwana glacial aspect, but those of the northern Qiangtang show more resemblance to those of the ancient Tethys. The two assemblages are interpreted as representing, respectively, the northern margin of Gondwanaland and the southwestern margin of the Yangtze continent. The two continents are suggested to have begun to separate during the Early Carboniferous and to have rejoined in the earliest Permian. Throughout this cycle of events, the northern Qiangtang occupied a passive margin while the southern Qiangtang rocks show evidence of the development of an active margin. Basaltic rocks from the southern Qiangtang are indicative of rifting. The authors consider that the boundary separating Car-boniferous and Permian rocks of Gondwanaland and Eurasia in the Qiangtang is marked by a suture zone that extends from Lungmuco through Heitonshan, Lake Gangma, Chasang, and Dongshuanghu. This suture is linked to Lancangjiang to the east and extends on to Malaya. In the Qiangtang the suture zone is marked by evidence of substantial rifting and by dismembered ophiolites. 相似文献
12.
DEFINITING AND ITS GEOLOGIC MEANING OF SOUTH-NORTH TREND FAULTED STRUCTURE BELT IN QIANGTANG BASIN, NORTH PART OF TIBET 总被引:5,自引:1,他引:4
There were more expounding to north—west (west) trend fault and north\|east trend fault within Qiangtang Basin, North Part of Tibet, in the past literature. With increasing of geophysical exploration data, nearly east\|west trend structure began to be taken note to. Since the year of 1995, by a synthetic study to geophysical and geological data, that south\|north trend faulted structures are well developed. These structures should be paid much more attention to, because they have important theoretical meaning and practical significance.1 Spreading of south\|north faulted structure belt According to different geological and geophysical data, the six larger scale nearly south\|north faulted structure belt could be distinguished within the scope of east longitude 84°~96° and near Qiangtang Basin. The actual location of the six belts are nearly located in the west of the six meridian of east longitude 85°,87°,89°,91°,93°,95° or located near these meridian. The six south\|north faulted structure belts spread in the same interval with near 2° longitude interval. The more clear and much more significance of south\|north trend faulted structure belts are the two S—N trend faulted structure belts of east longitude 87° and 89°. There are S—N trend faulted structure belts in the west of east longitude 83°,81°, or near the longitudes. The structure belts spreading features,manifestation,geological function and its importance, and inter texture and structure are not exactly so same. The structure belts all different degree caused different region of geological structure or gravity field and magnetic field. There is different scale near S—N trend faulted structure belt between the belts. 相似文献
13.
José Fernando Simancas Antonio Azor David Martínez-Poyatos Abdelfatah Tahiri Hassan El Hadi Francisco González-Lodeiro Andrés Pérez-Estaún Ramón Carbonell 《Comptes Rendus Geoscience》2009,341(2-3):103-113
The Iberian Massif poses a problem of relationships between its northwestern and southern parts. Suture terranes (ophiolites and high-pressure rocks) crop out in NW Iberia but only as allochthonous units, unconnected from their root zone. Sutures cropping out in SW Iberia are discussed in order to relate them to the unknown root of the NW Iberia allochthons. On the other hand, the Moroccan Variscides are very briefly presented with a view to propose their correlation with the Iberian zones. Particularly important is the transition from the Variscides to the Paleoproterozoic basement in Morocco, which is a key argument for palaeogeographic reconstructions. 相似文献
14.
Hugh Rollinson 《地学前缘(英文版)》2017,8(6):1253-1262
Oman has two ophiolites – the better known late Cretaceous northern Oman (or Semail) ophiolite and the lesser known and smaller, Jurassic Masirah ophiolite located on the eastern coast of the country adjacent to the Indian Ocean. A number of geological, geochronological and geochemical lines of evidence strongly suggest that the northern Oman ophiolite did not form at a mid-ocean ridge but rather in a supra-subduction zone setting by fast spreading during subduction initiation. In contrast the Masirah ophiolite is structurally part of a series of ophiolite nappes which are rooted in the Indian Ocean floor. There are significant geochemical differences between the Masirah and northern Oman ophiolites and none of the supra-subduction features typical of the northern Oman ophiolite are found at Masirah. Geochemically Masirah is MORB, although in detail it contains both enriched and depleted MORB reflecting a complex source for the lavas and dykes. The enrichment of this source predates the formation of the ophiolite. The condensed crustal section on Masirah (ca. 2 km) contains a very thin gabbro sequence and is thought to reflect its genesis from a cool mantle source associated with the early stages of sea-floor spreading during the early separation of eastern and western Gondwana. These data suggest that the Masirah ophiolite is a suitable analogue for an ophiolite created at a mid-ocean ridge, whereas the northern Oman ophiolite is not. The stratigraphic history of the Masirah ophiolite shows that it remained a part of the oceanic crust for ca. 80 Ma. The chemical variability and enrichment of the Masirah lavas is similar to that found elsewhere in Indian Ocean basalts and may simply reflect a similar provenance rather than a feature fundamental to the formation of the ophiolite. 相似文献
15.
From rifting to spreading in the eastern Gulf of Aden: a geophysical survey of a young oceanic basin from margin to margin 总被引:1,自引:0,他引:1
Sylvie Leroy Pascal Gente Marc Fournier Elia d'Acremont Philippe Patriat Marie-Odile Beslier Nicolas Bellahsen Marcia Maia Angelina Blais Julie Perrot Ali Al-Kathiri Serge Merkouriev Jean-Marc Fleury Pierre-Yves Ruellan Claude Lepvrier Philippe Huchon 《地学学报》2004,16(4):185-192
A geophysical survey in the eastern Gulf of Aden, between the Alula–Fartak (52°E) and the Socotra (55°E) transform faults, was carried out during the Encens–Sheba cruise. The conjugate margins of the Gulf are steep, narrow and asymmetric. Asymmetry of the rifting process is highlighted by the conjugate margins (horst and graben in the north and deep basin in the south). Two transfer fault zones separate the margins into three segments, whereas the present‐day Sheba Ridge is divided into two segments by a transform discontinuity. Therefore segmentation of the Sheba Ridge and that of the conjugate margins did coincide during the early stages of oceanic spreading. Extensive magma production is evidenced in the central part of the western segment. Anomaly 5d was identified in the northern and southern parts of the oceanic basin, thus confirming that seafloor spreading in this part of Gulf of Aden started at least 17.6 Ma ago. 相似文献
16.
西藏安多地区粗面岩的特征及其锆石SHRIMP U-Pb定年 总被引:3,自引:2,他引:1
安多粗面岩位于班公湖-怒江缝合带中段,紧邻安多蛇绿岩带的北侧,出露面积约30km2,堆积厚度约1500m,属陆相火山岩。火山机构面貌保存较完整。岩石类型包括安粗岩、石英安粗岩、粗面岩及少量火山碎屑岩,以粗面岩为主,属钾玄岩系列。岩石地球化学和同位素示踪特征表明岩石属相对高压型的粗面岩,是与大陆碰撞后造山有关的钾质火山岩。岩浆主要来源于加厚的陆壳下部,但也有幔源组分的贡献。粗面岩中锆石SHRIMP U-Pb年龄为79.9Ma±1.9Ma,是粗面质岩浆上侵结晶的年龄,表明安多粗面岩的喷溢时代为晚白垩世, 也暗示班公湖-怒江洋盆安多段早白垩世晚期已经闭合,晚白垩世时期羌塘地块与拉萨地块已成为统一的陆块,并具有加厚的陆壳。 相似文献
17.
PRESENT LANDFORMS, ACTIVE TECTONIC ZONES, DEEP STRUCTURES AND UPLIFT MECHANISMS OF THE LONGSHOUSHAN BLOCK ON THE NORTHERN MARGIN OF THE QINGHAI—TIBET PLATEAU 相似文献
18.
S. G. Skolotnev A. A. Peyve N. N. Turko M. E. Bylinskaya L. A. Golovina 《Geotectonics》2009,43(5):358-378
New data are obtained on the structure, evolution, and origin of zones of nontransform offsets of adjacent segments in the
Mid-Atlantic Ridge (MAR), which, in contrast to transform fracture zones, so far are studied insufficiently. The effects of
deep mantle plumes developing off the crest of the MAR on the processes occurring in the spreading zone are revealed. These
results are obtained from the geological investigation of the crest of the MAR between 19.8 ° and 21° S, where bottom sampling,
bathymetric survey, and magnetic measurements have been carried out previously. Two segments of the rift valley displaced
by 10 km relative to each other along a nontransform offset are revealed. A volcanic center of a spreading cell, which has
been active over the last 2 Ma, is located in the northern part of the southern segment and distinguished by a decreased depth
of the rift valley and increased thickness of the crust. Magnesian, slightly evolved basalts of the N-MORB type are detected
in this center, whereas evolved and high-Fe basalts are found beyond it. The variation in the composition of the basalts indicates
that the volcanic center is related to the upwelling of the asthenospheric mantle, which spread along and across the spreading
ridge. In the lithosphere, the melt migrated off the volcanic center along the rift valley. In the northern segment, a vigorous
volcanic center arose 2.5 Ma ago near its southern end; at present, the volcanic activity has ceased. As a result of the volcanic
activity, an oval rise composed of enriched T-MORB-type basalts was formed at the western flank of the crest zone. The isotopic
signatures show that the primary melts are derivatives of the chemically heterogeneous mantle. The mixing of material of the
depleted mantle with the mantle material pertaining either to the Saint Helena or the Tristan da Cunha plumes is suggested;
the mixture of all three sources cannot be ruled out. The conclusion is drawn that the mantle material of the Saint Helena
plume was supplied to the melting zone beneath the axial rift near the oval rise along a linear permeable zone in the mantle
extending at an azimuth of 225° SW. The blocks of mantle material that got to the convecting mantle from the Tristan da Cunha
plume at the stage of supercontinent breakup were involved in melting as well. The nontransform offset between the two segments
arose on the place of a previously existing transform fracture zone about 5 Ma ago. The nontransform offset developed in the
regime of oblique spreading at the progressive propagation of the southern segment to the north. The zone of nontransform
offset is characterized by recent volcanic activity. Over the last 2 Ma, spreading of the studied MAR segment was asymmetric,
faster in the western direction. The rates of westward and eastward half-spreading in the northern segment are estimated at
1.88 and 1.60 cm/yr, respectively. 相似文献
19.
中国东北地区蛇绿岩 总被引:12,自引:10,他引:2
我国东北地区位于中亚造山带的东段,经历了复杂的增生造山过程,其所属微陆块的基底属性及拼贴位置、洋-陆转换一直是地学界研究的热点。根据近年来的研究进展,我们将东北地区微陆块划分为额尔古纳地块、兴安增生地体、松嫩-锡林浩特地块和佳木斯地块。同时综述了东北地区蛇绿岩/蛇绿混杂岩带的时空分布、年代学及地球化学的新资料,讨论了其构造背景及俯冲-增生过程。东北地区增生造山不仅涉及古亚洲洋和古太平洋,还可能与泛大洋有关,包括早奥陶世-晚三叠世古亚洲洋主洋盆及古亚洲洋分支——新元古代-晚寒武世新林-喜桂图洋、早寒武世-晚石炭世嫩江洋、新元古代-晚志留世黑龙江洋和晚二叠世-中侏罗世牡丹江洋的演化。早石炭世末-晚石炭世初,东北地区古亚洲洋分支洋盆全部闭合,所有微陆块完成聚合形成统一的东北陆块群。晚二叠世-早三叠世时期,古亚洲洋主洋盆沿索伦-西拉木伦-长春-延吉缝合带自西向东从早到晚以剪刀式最终闭合,完成东北陆块群与华北板块的拼接。晚三叠世-早侏罗世时期古太平洋板块俯冲启动,东北地区进入古太平洋俯冲增生构造体系。 相似文献
20.
《Journal of African Earth Sciences》2010,57(4-5):167-178
Deformed conglomeratic clasts exposed along the Neoproterozoic Nakasib Suture and the Oko Shear Zone are used to calculate three-dimensional (3D) tectonic strain associated with the latter to quantify strain associated with post-accretionary deformational belts in the Arabian–Nubian Shield. The Nakasib Suture is a NE-trending fold and thrust belt that is sinistrally offset (∼10 km) by the cross-cutting NNW- to NW-trending strike-slip faults of the Oko Shear Zone. The Nakasib Suture was formed as a result of collision between the Haya terrane and the Gebeit terrane at ∼750 Ma ago. The Oko Shear Zone was subsequently formed as a result of an E–W directed shortening of the Arabian–Nubian Shield due to collision between East and West Gondwana at ∼670–610 Ma ago. This analysis indicates the following: (1) The Nakasib Suture is dominated by flattening strain with the flattening plane of the associated strain ellipsoid oriented at 21°/77°SE. This flattening deformation is interpreted to be associated with nappe emplacement from north to south. (2) Some regions along the Nakasib Suture are characterized by constriction strain that might be due to refolding of the early nappes about NE-trending axes. (3) The Oko Shear Zone is characterized by constriction strain, with the XY plane of the strain ellipsoid oriented at 171°/68°E. The strain ellipsoid associated with the Oko Shear Zone manifests superimposition of E–W shortening on the NE-trending fold and thrust belt associated with the Nakasib Suture. (4) The tectonic strain of the Oko Shear Zone, superimposed over the structures of the Nakasib Suture, is characterized by a strain ellipsoid whose flattening plane is oriented at 21°/49°W. The strain ellipsoid of the tectonic strain has a major axis with a quadratic elongation of 3.6 and an orientation of 357°/25°, an intermediate axis with a quadratic elongation of 1.2 and an orientation of 231°/30°, and a minor axis with a quadratic elongation of 0.25 and an orientation of 115°/18°. This suggests that the post-accretionary deformation of the Arabian–Nubian Shield was superimposed as a NW–SE directed shortening that created early N–S shortening zones and late NW-trending sinistral strike-slip faults. 相似文献