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1.
The Swiss Prealpine Dranse nappe consists of the badly known shaley Complexe de base series and the overlying Campanian to Maastrichtian Helminthoid Flysch. Our preliminary data from the shaley series indicate an Albian to Early Campanian age. It represents mid-slope to abyssal plain starved basin sediments. The occurrence of similar and coeval series in the Carpathians and Ligurian Alps suggest common tectonic and oceanographic conditions. 相似文献
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Florian Genier Jean-Luc Epard François Bussy Tomas Magna 《Swiss Journal of Geoscience》2008,101(2):431-452
Detailed field work and zircon analysis have improved the knowledge of the lithostratigraphy at the base of the Siviez-Mischabel nappe in the Mattertal (St-Niklaus-Törbel area). They confirm the existence of an overturned limb and clarify the structure of the St-Niklaus syncline. The following formations can be observed:
- Polymetamorphic gneisses; composed of paragneisses, amphibolites and micaschists (Bielen Unit, pre-Ordovician).
- Fine-grained, greyish quartzite and graywacke with kerogen-rich horizons (Törbel Formation, presumed Carboniferous).
- Green or white micaschists characterized by brown carbonate spots associated with white conglomeratic quartzites (Moosalp Formation, Early Permian).
- Massive, green or white, fine grained, microconglomeratic or conglomeratic quartzites with characteristic pink quartz pebbles (Bruneggjoch Formation, Late Permian-Early Triassic).
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Marián Putiš Hans-Jürgen Gawlick Wolfgang Frisch Marián Sulák 《International Journal of Earth Sciences》2008,97(4):799-819
The Cretaceous orogen of the Western Carpathians comprises fragments of the destructed northern Centrocarpathian domain, which
is defined as Infratatric unit and formed a continental margin facing the Penninic Ocean in Jurassic and Cretaceous times.
The breakup event and opening of the Penninic Ocean occurred in the Early Jurassic (Pliensbachian), which is recorded by an
abrupt deepening event from shallow-water sediments to deep-water nodular limestone in the Infratatric sediment succession.
The transformation of the passive into an active continental margin by the onset of subduction of the Penninic oceanic crust
occurred in Santonian times and is reflected by the beginning of flysch deposition in the Infratatric Belice domain, which
took the position of a forearc basin in the convergent margin setting. The forearc basin was supplied by clastic material
from the more internal part of the Infratatric unit, which experienced nappe stacking, metamorphism, and subsequent exhumation
in Late Cretaceous times. In the frontal part of the forearc basin an accretionary wedge was built up, which formed an outer-arc
ridge and delivered detrital material into the forearc basin in Maastrichtian time. Final collision between the European and
the Adriatic plate occurred in the Eocene period and is responsible for weak metamorphism in the Infratatric unit. 相似文献
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《Journal of African Earth Sciences》1999,28(2):443-463
Sediments of the Ordovician to Devonian Sinakumbe Group (∼210 m thick) and overlying Upper Carboniferous to Lower Jurassic Karoo Supergroup (∼4.5 km thick) were deposited in the mid-Zambezi Rift Valley Basin, southern Zambia.The Sinakumbe-Karoo succession represents deposition in a extensional fault-controlled basin of half-graben type. The basin-fill succession incorporates two major fining-upward cycles that resulted from major tectonic events, one event beginning with Sinakumbe Group sedimentation, possibly as early as Ordovician times, and the other beginning with Upper Karoo Group sedimentation near the Permo-Triassic boundary. Minor tectonic pulses occurred during deposition of the two major cycles. In the initial fault-controlled half-graben, a basin slope and alluvial fan system (Sikalamba Conglomerate Formation), draining southeastward, was apparently succeeded, without an intervening transitional facies, by a braided river system (Zongwe Sandstone Formation) draining southwestward, parallel to the basin margin. Glaciation followed by deglaciation resulted in glaciofluvial and glacio-lacustrine deposits of the Upper Carboniferous to Lower Permian Siankondobo Sandstone Formation of the Lower Karoo Group, and isostatic rebound eventually produced a broad flood plain on which the coal-bearing Lower Permian Gwembe Coal Formation was deposited. Fault-controlled maximum subsidence is represente by the lacustrine Upper Permian Madumabisa Mudstone Formation. Block-faulting and downwarping, probably due to the Gondwanide Orogeny, culminated with the introduction of large quantities of sediment through braided fluvial systems that overwhelmed and terminated Madumabisa Lake sedimentation, and is now represented by the Triassic Escarpment Grit and Interbedded Sandstone and Mudstone Formations of the Upper Karoo Group. Outpourings of basaltic flows in the Early Jurassic terminated Karoo sedimentation. 相似文献
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华北地台北缘乌兰哈雅地区发现二叠纪未-三叠纪初蒙古寺-盘羊山-乌兰哈雅推覆构造,将晚太古代色尔腾山岩群绿片岩系推覆到震旦系什那干组灰岩和古生代碎屑岩系之上.推覆面走向近东西向,延伸长度大于50 kn,推覆方向180~230o,推覆距离大于4.5 km.推覆界面被中三叠世(U-Pb同位素年龄231 Ma)二长花岗岩侵入,又被中侏罗统大青山组不整合覆盖.本推覆构造的发现改变了前人认为本区不存在古生代末大型推覆构造的看法,对了解华北地台(板块)构造发展历史与地壳演化有重要意义.说明华北地台(板块)晚古生代末存在大型陆内造山事件,其动力来源推测为华北板块与华南板块的碰撞所产生的巨大挤压应力. 相似文献
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为寻找潜在的煤炭资源,通过对石拐盆地西段地表及地下构造特征的分析,认为大青山逆冲推覆构造的前缘应为F10断层组;地表的长汉沟组等地层是从3 km外的南部推覆而来的外来岩层;深部的五当沟组一段主含煤地层基本未受推覆构造影响,且该地层应比其地表位置更向南;盆地南缘的二叠系下应有未受推覆构造影响的原生煤层。 相似文献
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Prof. Dr. W. Frisch 《International Journal of Earth Sciences》1984,73(1):33-45
Late Mesozoic subduction of Penninic oceanic lithosphere finds its response in the sedimentary record. The corresponding sediments are deposited in a deep-sea trench environment and are developed as distal, partly proximal flysches, containing breccias and olistolites, which are up to kilometer-sized (wildflysch). In the Tauern window this facies is represented by the Nordrahmen zone, which is the equivalent to the Matrei zone. It is proposed to apply the term “Matrei zone” to the entire zone. It forms the high parts of the Bündner Schiefer and Tauernflysch formation. The olistolites derive from the unstable Austroalpine continental margin (Lower Austroalpine). In the Unterengadin window the wildflysch faciès is found in North, Middle and South Penninic position. In that there are kilometer-sized blocks of clearly Lower Austroalpine provenance in a North Penninic position, the Middle Penninic Tasna zone must already have been subducted at the time of emplacement of these olistolites. The Tasna zone itself contains a number of olistolites and disintegrates towards the northeast into a wildflysch zone. Its nappe character is discussed. After earlier fossil findings it is likely that the lower flysch zones of the Unterengadin window contain younger members than the higher ones. Thus, a mechanism of offscraping of the trench sediments and piling up in an accreting wedge above a subduction zone is proposed. 相似文献
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H.-J. Gawlick W. Frisch A. Vecsei T. Steiger F. Böhm 《International Journal of Earth Sciences》1999,87(4):644-657
Facies analysis, fossil dating, and the study of the metamorphism in the Late Triassic to Early Cretaceous sedimentary successions in the central part of the Northern Calcareous Alps allow to reconstruct the tectonic evolution in the area between the South Penninic Ocean in the northwest and the Tethys Ocean with the Hallstatt Zone in the southeast. The Triassic as well as the Early and Middle Jurassic sediments were deposited in a rifted, transtensive continental margin setting. Around the Middle/Late Jurassic boundary two trenches in front of advancing nappes formed in sequence in the central part of the Northern Calcareous Alps. The southern trench (Late Callovian to Early Oxfordian) accumulated a thick succession of gravitatively redeposited sediments derived from the sedimentary sequences of the accreted Triassic–Liassic Hallstatt Zone deposited on the outer shelf and the margin of the Late Triassic carbonate platform. During a previous stage these sediments derived from sequences deposited on the more distal shelf (Salzberg facies zone of Hallstatt unit, Meliaticum), and in a later stage from more proximal parts (Zlambach facies zone of Hallstatt unit, Late Triassic reef belt). Low temperature–high pressure metamorphism of some Hallstatt limestones before redeposition is explained by the closure of parts of the Tethys Ocean in Middle to Late Jurassic times and associated subduction. In the northern trench (Late Oxfordian to Kimmeridgian) several hundred meters of sediment accumulated including redeposited material from a nearby topographic rise. This rise is interpreted as an advancing nappe front as a result of the subduction process. The sedimentary sealing by Tithonian sediments, documented by uniform deep-water sedimentation (Oberalm Formation), gives an upper time constraint for the tectonic events. In contrast to current models, which propose an extensional regime for the central and eastern Northern Calcareous Alps in the Late Jurassic, we propose a geodynamic model with a compressional regime related to the Kimmerian orogeny. 相似文献
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In the area of Arosa?CDavos?CKlosters (Eastern Switzerland) the different tectonic elements of the Arosa zone mélange e.g. the Austroalpine fragments, the sedimentary cover of South Penninic ophiolite fragments, as well as the matrix (oceanic sediments and flysch rocks) show distinctively different metamorphic histories and also different climaxes (??peaks??) of Alpine metamorphism. This is shown by a wealth of Kübler-Index, vitrinite and bituminite reflectance measurements, and K-white mica b cell dimension data. At least six main metamorphic events can be recognized in the area of Arosa?CDavos?CKlosters: (1) A pre-orogenic event, typical for the Upper Austroalpine and for instance found in the sediments at the base of the Silvretta nappe but also in some tectonic fragments of the Arosa zone (Arosa zone mélange). (2) An epizonal oceanic metamorphism observed in the close vicinity of oceanic basement rocks units of the Arosa zone (South Penninic) is another pre-orogenic process. (3) A metamorphic overprint of the adjacent Lower Austroalpine nappes and structural fragments of the Lower Austroalpine in the Arosa zone. This metamorphic overprint is attributed to the orogenic metamorphic processes during the Late Cretaceous. (4) A thermal climax observed in the South Penninic sediments of the Arosa zone can be bracketed by the Austroalpine Late Cretaceous event (3) and the middle Tertiary event (5) in the Middle Penninic units and predates Oligocene extension of the ??Turba phase??. (6) North of Klosters, in the northern part of our study area, the entire tectonic pile from the North Penninic flysches to the Upper Austroalpine is strongly influenced by a late Tertiary high-grade diagenetic to low-anchizone event. In the Arosa zone mélange an individual orogenic metamorphic event is evidenced and gives a chance to resolve diagenetic?Cmetamorphic relations versus deformation. Six heating episodes in sedimentary rocks and seven deformation cycles can be distinguished. This is well explained by the propagation of the Alpine deformation front onto the foreland units. Flysches at the hanging wall of the mélange zone in the north of the study area (Walsertal zone) show data typical for low-grade diagenetic thermal conditions and are therefore sandwiched between higher metamorphic rock units and separated from theses units by a disconformity. The Arosa zone s.s., as defined in this paper, is characterised by metamorphic inversions in the hanging wall and at the footwall thrust, thus shows differences to the Walsertal zone in the north and to the Platta nappe in the south. 相似文献
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内蒙古中部石拐侏罗纪陆相含煤盆地构造变形 总被引:1,自引:1,他引:0
对华北陆块北缘大青山推覆构造前缘石拐侏罗纪陆相含煤盆地的构造进行了分析。结果表明:早侏罗世早期,石拐盆地受NNE-SSW方向的拉张作用力,形成近东西走向的断陷盆地,而后沉积了早-中侏罗世五当沟组含煤沉积;中侏罗世末受近东西向挤压,在早先沉积地层中形成一套共轭节理;晚侏罗世受大青山推覆构造影响,盆地内侏罗系形成一系列代表推覆构造体系前缘带的紧闭同斜-直立宽缓褶皱及断层相关断层,具明显构造分带性。早侏罗世早期的拉张可能是印支造山后地壳的伸展垮塌,而晚侏罗世的挤压可能是板缘碰撞的板内响应。 相似文献
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A. Cerrina Feroni L. Leoni L. Martelli P. Martinelli G. Ottria G. Sarti 《Geological Journal》2001,36(1):39-54
The study of clast composition carried out on the alluvial gravels of the Romagna Apennines of northern Italy has provided evidence for an extensive covering of allochthonous units (Ligurian nappe and Epiligurian succession) above the Miocene foredeep deposits (Marnoso‐Arenacea Formation), which has been subsequently eroded during the Late Miocene–Pleistocene uplift. This result is confirmed by the burial history outlined in the Marnoso‐Arenacea Formation through vitrinite reflectance and apatite fission‐track analyses. The Romagna Apennines represent, therefore, a regional tectonic window where the thrust system that displaced the Marnoso‐Arenacea Formation crops out. The geometric relations between this thrust system and the basal thrust of the Ligurian nappe, exposed at the boundaries of the Romagna Apennines (Sillaro Zone and Val Marecchia klippe), are consistent with a duplex structure. Thus, the Romagna Apennines thrust system is an eroded duplex. The duplex roof‐thrust corresponds to the surface of the synsedimentary overthrust of the Ligurian nappe on the Marnoso‐Arenacea Formation; the floor‐thrust is located in the pelagic pre‐foredeep deposits (Schlier Formation). Copyright © 2001 John Wiley & Sons, Ltd. 相似文献
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Structural development of the Tso Morari ultra-high pressure nappe of the Ladakh Himalaya 总被引:2,自引:0,他引:2
A continental subduction-related and multistage exhumation process for the Tso Morari ultra-high pressure nappe is proposed. The model is constrained by published thermo-barometry and age data, combined with new geological and tectonic maps. Additionally, observations on the structural and metamorphic evolution of the Tso Morari area and the North Himalayan nappes are presented. The northern margin of the Indian continental crust was subducted to a depth of > 90 km below Asia after continental collision some 55 Ma ago. The underthrusting was accompanied by the detachment and accretion of Late Proterozoic to Early Eocene sediments, creating the North Himalayan accretionary wedge, in front of the active Asian margin and the 103–50 Ma Ladakh arc batholith. The basic dikes in the Ordovician Tso Morari granite were transformed to eclogites with crystallization of coesite, some 53 Ma ago at a depth of > 90 km (> 27 kbar) and temperatures of 500 to 600 °C. The detachment and extrusion of the low density Tso Morari nappe, composed of 70% of the Tso Morari granite and 30% of graywackes with some eclogitic dikes, occurred by ductile pure and simple shear deformation. It was pushed by buoyancy forces and by squeezing between the underthrusted Indian lithosphere and the Asian mantle wedge. The extruding Tso Morari nappe reached a depth of 35 km at the base of the North Himalayan accretionary wedge some 48 Ma ago. There the whole nappe stack recrystallized under amphibolite facies conditions of a Barrovian regional metamorphism with a metamorphic field gradient of 20 °C/km. An intense schistosity with a W–E oriented stretching lineation L1 and top-to-the E shear criteria and crystallization of oriented sillimanite needles after kyanite, testify to the Tso Morari nappe extrusion and pressure drop. The whole nappe stack, comprising from the base to top the Tso Morari, Tetraogal, Karzok and Mata–Nyimaling-Tsarap nappes, was overprinted by new schistosities with a first N-directed and a second NE-directed stretching lineation L2 and L3 reaching the base of the North Himalayan accretionary wedge. They are characterized by top-to-the S and SW shear criteria. This structural overprint was related to an early N- and a younger NE-directed underthrusting of the Indian plate below Asia that was accompanied by anticlockwise rotation of India. The warping of the Tso Morari dome started already some 48 Ma ago with the formation of an extruding nappe at depth. The Tso Morari dome reached a depth of 15 km about 40 Ma ago in the eastern Kiagar La region and 30 Ma ago in the western Nuruchan region. The extrusion rate was of about 3 cm/yr between 53 and 48 Ma, followed by an uplift rate of 1.2 mm/yr between 48 and 30 Ma and of only 0.5 mm/yr after 30 Ma. Geomorphology observations show that the Tso Morari dome is still affected by faults, open regional dome, and basin and pull-apart structures, in a zone of active dextral transpression parallel to the Indus Suture zone. 相似文献
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In the Bavarian Alps (Germany), west of the Isar River, the abyssal deposits of the Lower Barremian to Upper Campanian Rhenodanubian Group consist of siliciclastic and calcareous turbidites alternating with hemipelagic non-calcareous mudstones. The up to 1500-m-thick succession, deposited in the Penninic Basin to the south of the European Plate, is characterized by a low mean sedimentation rate (c. 25 mm kyr−1) over 60 million years. Palaeocurrents and turbidite facies distribution patterns suggest that sedimentation occurred on a weakly inclined abyssal plain. The highest sedimentation rates (up to 240 mm kyr−1) were associated with the calcareous mud turbidites of the newly defined Röthenbach Subgroup, which includes the Piesenkopf, Kalkgraben and Hällritz formations (Middle Coniacian to Middle Campanian). These calcareous turbidites prograded from the west, and interfinger towards the east with red hemipelagic claystone. A high sea level presumably favoured pelagic carbonate production and accumulation on the shelves and on internal platforms in the western part of the basin, whereas siliciclastic shelves with steep slope angles have bordered the eastern part of the basin, where a dearth of turbidite sedimentation and increased Cretaceous oceanic red beds deposition occurred. In contrast to the eustatically-induced Middle Coniacian to Lower Campanian Cretaceous oceanic red beds (calcareous nannoplankton zones CC14 to CC18), red hemipelagites of Early Cenomanian age (upper part of calcareous nannoplankton zone CC9) and early Late Campanian age (upper part of zone CC21 and zone CC22) are interpreted as the result of regional tectonic activity. 相似文献
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鄂尔多斯北缘石合拉沟逆冲推覆构造的发现及意义 总被引:12,自引:0,他引:12
最近在包头市幅1/25万区域地质调查工作中,在黄河南部鄂尔多斯北缘隆起带中发现了由北向南逆冲的石合拉沟推覆构造。上盘逆冲推覆体由基底浅变质的石英岩、黑云变粒岩和大理岩构成,推覆在晚石炭统太原组和中三叠统二马营组之上。野外地质关系表明逆冲推覆变形作用发生在晚侏罗世,与河套新生代断陷盆地北缘大青山逆冲推覆构造晚期逆冲推覆变形作用是同时的,逆冲推覆方向相反,构成了以现代河套盆地为中心的晚侏罗世背冲型逆冲推覆构造。该逆冲推覆构造的发现对探讨华北地台北缘中生代地壳构造变形特点和新生代河套断陷盆地基底构造性质具有重要意义。 相似文献