首页 | 本学科首页   官方微博 | 高级检索  
相似文献
 共查询到20条相似文献,搜索用时 218 毫秒
1.
In the Phyllite Group of Crete a stratigraphic succession from Permian to Upper Triassic members is represented. In Carnian parts of this succession in eastern Crete a coherent sheet of Hercynian amphibolites and micaschists is included. It is 20 km long and up to 300 m thick. The Hercynian metamorphics are shown to have been thrusted upon the pre-Carnian part of the Phyllite Group before the Carnian sedimentation continued. A strong, andesitic volcanism was connected with this thrusting in time and space. Tectonic events like these are not known in the outer zones of the Hellenides until now.  相似文献   

2.
  1. In the Earth history not a system probably comprises so many evaporites than Triassic. They are not restricted to such or such protoocean but cover huge epicontinental cratonic plateforms with very finely bedded deposits as well as they fill rifts located in very diversified geodynamic areas. The first condition in order that such deposits can exist is a severe aridity.
  2. Triassic corresponds to an extraordinary transgression in the sense of a new onlap of the sedimentary realm, a reconquest of ancient areas by new deposits, however their facies may be. In that general setting evaporites are themselves remarkably transgressive and from two points of view a) they sometimes onlap directly — that is to say without any basal detritic intercalation — different terms of peneplaned basement, b) these evaporites often succeed Permian emersion or continental detritic deposits of lower parts of Triassic. They extract their salts from Ocean. They often underlie pure marine Jurassic facies. For all these reasons evaporites appear as the first emissaries of oceanic realm and so as the first witnesses of a marine transgression.
  3. Evaporites occur in Triassic, particularly in the Middle East, North Africa, on the two present margins of North Atlantic, on Western and Northern Europe, etc. The whole constitutes a huge saline ring round the western part of Triassic Tethysian sea. In that area, on the less tectonized plateforms a grandiose facies distribution pattern appears clearly: going farther from open sea in a centrifugal way, there are salts more and more soluble, until detritic deposits from continent. The pellicular sheets of water which covered the large plateforms resulting from late permian peneplanation should be favourable to modification of chemism, very gradual and at last very total, producing a geographical distribution of salt deposits. The most probable mover of these “floods” could be a very likely multiphase rise of eustatic level, the effects of which we cannot imagine because they occured on plateforms unknown in the geography of recent world. Effects of local morphology which induced a pecular distribution of salts can modify the general plateform distribution pattern.
  相似文献   

3.
The Trypali carbonate unit (Upper Triassic), which crops out mainly in central‐western Crete, occurs between the parautochthonous series (Plattenkalk or Talea Ori‐Ida series, e.g. metamorphic Ionian series) and the Tripolis nappe (comprising the Tripolis carbonate series and including a basal Phyllite–Quartzite unit). It consists of interbedded dolomitic layers, represented principally by algally laminated peloidal mudstones, foraminiferal, peloidal and ooidal grainstones, as well as by fine‐grained detrital carbonate layers, in which coarse baroque dolomite crystals and dolomite nodules are dispersed. Baroque dolomite is present as pseudomorphs after evaporite crystals (nodules and rosettes), which grew penecontemporaneously by displacement and/or replacement of the host sediments (sabkha diagenesis). However, portions of the evaporites show evidence of resedimentation. Pre‐existing evaporites predominantly consisted of skeletal halite crystals that formed from fragmentation of pyramidal‐shaped hoppers, as well as of anhydrite nodules and rosettes (salt crusts). All microfacies are characteristic of peritidal depositional environments, such as sabkhas, tidal flats, shallow hypersaline lagoons, tidal bars and/or tidal channels. Along most horizons, the Trypali unit is strongly brecciated. These breccias are of solution‐collapse origin, forming after the removal of evaporite beds. Evaporite‐related diagenetic fabrics show that there was extensive dissolution and replacement of pre‐existing evaporites, which resulted in solution‐collapse of the carbonate beds. Evaporite replacement fabrics, including calcitized and silicified evaporite crystals, are present in cements in the carbonate breccias. Brecciation was a multistage process; it started in the Triassic, but was most active in the Tertiary, in association with uplift and ground‐water flow (telogenetic alteration). During late diagenesis, in zones of intense evaporite leaching and brecciation, solution‐collapse breccias were transformed to rauhwackes. The Trypali carbonate breccias (Trypali unit) are lithologically and texturally similar to the Triassic solution‐collapse breccias of the Ionian zone (continental Greece). The evaporites probably represent a major diapiric injection along the base of the parautochthonous series (metamorphic Ionian series) and also along the overthrust surface separating the parautochthonous series from the Tripolis nappe (Phyllite–Quartzite and Tripolis series). The injected evaporites were subsequently transformed into solution‐collapse breccias.  相似文献   

4.
This work describes a geological scheme of the pre- And ean Domeyko Range of Northern Chile. This pre- And ean area consists of a basement formed by Paleozoic granitic, volcanic, and marine sedimentary rocks, and by Triassic acidic volcanics with continental intercalations. The Andean Basin developed in the Lias over the basement, with initial stages that include volcanic and continental sequences. A continuous marine environment existed in the Hettangian-Tithonian span, with volcanic events in the Bajocian, Callovian, Kimmeridgian, and Tithonian. Evaporitic facies developed in the Oxfordian-Kirnmeridgian. A marine-continental basin is recognized in the Neocomian, the Upper Cretaceous being represented by volcanic and continental deposits, a development similar to the Tertiary one; over these sequences volcanic, detrital, and saline deposits were laid down in the Plio-Pleistocene. Compressional tectonic cycles developed in the Upper Paleozoic, Upper Lias?, Upper Jurassic, Upper Cretaceous, and Tertiary, and tensional phases occured in the Triassic, Cretaceous, and Tertiary. The compressional stages were characterized by intrusive cycles while the tensional phases witnessed volcanic sedimentary events.  相似文献   

5.
Caliches: Large areas of the northern Sahara and the Algerian High Planes are covered by mostly 1–5 m thick caliches. Their age (Pliocene in the Sahara) decreases to the north and their precipitation is generally independent of groundwater. Their profile is composed (from top to base) as follows:
  • Upper soil, loose and mostly of eolian origin.
  • Upper part of caliche, with very characteristic, dense, partly layered-knobby texture, formed slowly by solutional and reprecipitational processes of ± freely outcropping caliches under addition of eolian material.
  • Under part of caliche, highly porous, somewhat chalky and greyish-white; precipitated mainly by capillar rise of solutions in permeable and calcareous rocks.
  • Substratum, preferentially calcareous sandstones, alluvial deposits and marls.
    • The mineralogy of the caliches (whose main components are represented in fig. 4 A-C) is rather monotonous: in addition to relicts of the substratum (partly dissolved or pushed aside by precipitation of calcite), there are only newly formed low-Mg-calcite and some quarzine (length-slow quartz). Sr-contents of calcite rise clearly from substratum to upper part of caliche. Gypsiferous Crusts (or Cementations): They are found mainly in the surroundings of Chotts (flat, ± saline lakes) and in oases of the NE-Algerian Sahara. Their formation began — mostly caused climatically — after the period of caliche formation and is still continuing in some places. Most of these gypsum-crusts are formed by evaporation of near-surface groundwaters in sandy soils. Water saturated in gypsum precipitates large crystals of gypsum (relatively low in Sr), partly filled by sand, at groundwater-surface. Fine crystalline crusts (relatively high in Sr) are formed by ascendent waters with lower gypsum content ± directly under the landsurface.  相似文献   

    6.
    The transition from the shallow marine Upper Muschelkalk Sea to the Lower Keuper fluvial plain represents the most diachronous facies shift of the entire Germanic Triassic. The type-section of the fluvial Lower Keuper (Erfurt Formation) is described in detail for the first time including biostratigraphic dating of the Muschelkalk/Keuper boundary. The type-section is integrated into a NNE-SSW cross section through the Central European Basin, and the Muschelkalk/Keuper facies shift is constrained by high-resolution conodont and ceratite biostratigraphy. Thus, the fundamental changes in palaeogeography, shifts of facies belts and stratal pattern architecture are visualised. Forced by a rapid transgression from Tethyan waters, the shallow marine Upper Muschelkalk Sea attained its maximum flooding in the lower conodont zone 2 (sequens/pulcher to philippi/robustus zones). Subsequent slow continuous regression to the South was accompanied by step-by-step progradation of coastal to fluvial plain environments of the Lower Keuper, culminating in a fluvial plain extending to South Germany. Based on stratal patterns, an improved sequence-stratigraphic interpretation for the Upper Muschelkalk/Lower Keuper interval is suggested. In combination with biostratigraphic arguments, the new sequence-stratigraphy points to a revised correlation of this interval within the Tethyan Triassic, incorporating the positions of the Anisian/Ladinian and Fassanian/Longobardian boundaries.  相似文献   

    7.
    The origin of quartz cement in sandstones can be attributed to supplies (1) from the surrounding shales, and (2) to a lower degree from dissolution of quartz on stylolites within the sandstones. A supply from the surrounding shales, which has been shown by the porosity decrease near the upper and lower surfaces of different sandstones (Füchtbauer, 1974), can be explained by the following observations in Upper Triassic and Middle Jurassic sandstones and siltstones of Northern Germany as well as in concretions of Devonian to Upper Cretaceous age from different localities:
    1. Quartz grains in silt layers are flattened by dissolution compared with quartz grains of the same size in the adjacent sandstones, the amount of shrinking being about 35 percent (fig. 1).
    2. Concretions prevent the enclosed insoluble residues from diagenesis. The main difference between the concretions and the adjacent shale of 31 occurrences examined is the quartz content, which is by 10–50 percent lower in the adjacent shale, due to diagenetical dissolution (fig. 2).
    It is suggested that the dissolved silica was brought to the sandstones by the compaction stream of interstitial water percolating through the rock sequence, and that the sandstones acted as sinks triggering the dissolution. Only a small amount of silica, about 10 percent of the silica from dissolved quartz, is provided by the transition montmorillonite — illite. Both sources together would be able to explain the precipitation of 20 percent quartz cement in a sequence composed of 1/3 sandstones and 2/3 shales. In the sandstones mentioned above stylolites can be observed (fig. 3), the amplitudes of which increase from 0,5–1 mm to 2–5 mm with increasing depth, between 1300 and 2600 metres. The real amount of dissolution on each stylolite — about 4 mm — has been calculated using large mica which were collected by the stylolites from the adjacent sandstone. Using this figure, the decrease of porosity in the sandstones shown in fig. 4 can be quantitatively explained by the frequency of stylolite intercalations. It is suggested that this process, which was due to local diffusion, occurred late in diagenesis, when the compaction stream was already insufficient to move large quantities of silica.  相似文献   

    8.
    The Malatya Basin is situated on the southern Taurus-Anatolian Platform. The southern part of the basin contains a sedimentary sequence which can be divided into four main units, each separated by an unconformity. From base to top, these are: (1) Permo-Carboniferous; (2) Upper Cretaceous–Lower Paleocene, (3) Middle-Upper Eocene and (4) Upper Miocene. The Upper Cretaceous–Tertiary sedimentary sequence resting on basement rocks is up to 700 m thick.The Permo-Carboniferous basement consist of dolomites and recrystallized limestones. The Upper Cretaceous–Lower Paleocene transgressive–regressive sequence shows a transition from terrestrial environments, via lagoonal to shallow-marine limestones to deep marine turbiditic sediments, followed upwards by shallow marine cherty limestones. The marine sediments contain planktic and benthic foraminifers indicating an upper Campanian, Maastrichtian and Danian age. The Middle-Upper Eocene is a transgressive–regressive sequence represented by terrestrial and lagoonal clastics, shallow-marine limestones and deep marine turbidites. The planktic and benthic foraminifers in the marine sediments indicate a Middle-Upper Eocene age. The upper Miocene sequence consists of a reddish-brown conglomerate–sandstone–mudstone alternation of alluvial and fluvial facies.During Late Cretaceous–Early Paleocene times, the Gündüzbey Group was deposited in the southern part of a fore-arc basin, simultaneously with volcanics belonging to the Yüksekova Group. During Middle-Late Eocene times, the Yeşilyurt Group was deposited in the northern part of the Maden Basin and the Helete volcanic arc. The Middle-Upper Eocene Malatya Basin was formed due to block faulting at the beginning of the Middle Eocene time. During the Late Paleocene–Early Eocene, and at the end of the Eocene, the study areas became continental due to the southward advance of nappe structures.The rock sequences in the southern part of the Malatya Basin may be divided into four tectonic units, from base to top: the lower allochthon, the upper allochthon, the parautochthon and autochthonous rock units.  相似文献   

    9.
    塔西南白垩系发育,可分为上、下两统。下白垩统克孜勒苏群可分4段,多以陆相沉积为主,富含棕红色砂砾岩夹少许砂岩、粉砂岩、泥岩和砾岩。上白垩统英吉沙群为海陆相并存,库克拜组可分2段,常见泥岩、膏岩和海相化石;乌依塔格组多为红色泥岩、泥质粉砂岩夹砂岩;依格孜牙组多见灰岩、白云质灰岩,富含海相化石;吐依洛克组为棕红色泥岩、石膏和砂、砾岩,含海相化石。通过勾勒9个岩性单元的沉积相展布,分析昆仑山前白垩纪的沉积环境演化过程。克孜勒苏群西区多为陆相快速堆积,东区远离陆源为三角洲和滨岸沉积,具有宽泛的冲积扇—辫状河三角洲相分布。库克拜组总体显示为辫状河三角洲—潮坪相变的过程;乌依塔格组以潮坪为主;依格孜牙组表现为碳酸盐岩台地—台地边缘的演化;吐依洛克组为宽广潮坪。  相似文献   

    10.
    The author's concept (1970, 1974) of evaluating metamorphic conditions is explained on the basis of most recent petrologic data. The major points treated are:
    1. Instead of usual petrographic mapping, petrographic work in the field is aimed at specific “targets”, i.e., rock compositions. This is so because only specific rocks may give petrogenetically relevant information in the four metamorphic grades.
    2. There are very many mineral reactions in metamorphism but only a few are petrogenetically significant. These are important to know, and they are graphically demonstrated. Any mineral assemblage that is formed by a significant mineral reaction must be verified as a paragenesis of mutually contacting minerals. Only such parageneses deserve to be mapped in the field as isograds or isoreactiongrads.
    3. Crossing isograds or isoreactionsgrads provide data on temperature and pressure during metamorphism for that part of a metamorphic terrane where the crossing has been observed.
    4. The sequence of isograds or isoreaction-grads may be a pressure indicator. Moreover, such a sequence provides geodynamic information whether a larger metamorphic area has been lifted up evenly or has been tilted while it was uplifted after metamorphism.
      相似文献   

    11.
    The stability relations between cordierite and almandite in rocks, having a composition of CaO poor argillaceous rocks, were experimentally investigated. The starting material consisted of a mixture of chlorite, muscovite, and quartz. Systems with widely varying Fe2+/Fe2++Mg ratios were investigated by using two different chlorites, thuringite or ripidolite, in the starting mixture. Cordierite is formed according to the following reaction: $${\text{Chlorite + muscovite + quartz}} \rightleftharpoons {\text{cordierite + biotite + Al}}_{\text{2}} {\text{SiO}}_{\text{5}} + {\text{H}}_{\text{2}} {\text{O}}$$ . At low pressures this reaction characterizes the facies boundary between the albite-epidotehornfels facies and the hornblende-hornfels facies, at medium pressures the beginning of the cordierite-amphibolite facies. Experiments were carried out reversibly and gave the following equilibrium data: 505±10°C at 500 bars H2O pressure, 513±10°C at 1000 bars H2O pressure, 527±10°C at 2000 bars H2O pressure, and 557±10°C at 4000 bars H2O pressure. These equilibrium data are valid for the Fe-rich starting material, using thuringite as the chlorite, as well as for the Mg-rich starting mixture with ripidolite. At 6000 bars the equilibrium temperature for the Mg-rich mixture is 587±10°C. In the Fe-rich mixture almandite was formed instead of cordierite at 6000 bars. The following reaction was observed: $${\text{Thuringite + muscovite + quartz}} \rightleftharpoons {\text{almandite + biotite + Al}}_{\text{2}} {\text{SiO}}_{\text{5}} {\text{ + H}}_{\text{2}} {\text{O}}$$ . Experiments with the Fe-rich mixture, containing Fe2+/Fe2++Mg in the ratio 8∶10, yielded three stability fields in a P,T-diagram (Fig.1):
    1. Above 600°C/5.25 kb and 700°C/6.5 kb almandite+biotite+Al2SiO5 coexist stably, cordierite being unstable.
    2. The field, in which almandite, biotite and Al2SiO5 are stable together with cordierite, is restricted by two curves, passing through the following points:
      1. 625°C/5.5 kb and 700°C/6.5 kb,
      2. 625°C/5.5 kb and 700°C/4.0 kb.
    3. At conditions below curves 1 and 2b, cordierite, biotite, and Al2SiO5 are formed, but no garnet.
    An appreciable MnO-content in the system lowers the pressures needed for the formation of almandite garnet, but the quantitative influence of the spessartite-component on the formation of almandite could not yet be determined. the Mg-rich system with Fe2+/Fe2++Mg=0.4 garnet did not form at pressures up to 7 kb in the temperature range investigated. Experiments at unspecified higher pressures (in a simple squeezer-type apparatus) yielded the reaction: $${\text{Ripidolite + muscovite + quartz}} \rightleftharpoons {\text{almandite + biotite + Al}}_{\text{2}} {\text{SiO}}_{\text{5}} {\text{ + H}}_{\text{2}} {\text{O}}$$ . Further experiments are needed to determine the equilibrium data. The occurence of garnet in metamorphic rocks is discussed in the light of the experimental results.  相似文献   

    12.
    The study deals with the comparison of corrosion forms in differently soluble rocks from different climatic regions, namely forms of the naked karst (lapies), depressions, and corrosive plains. The far-reaching morphographic conformity of corresponding forms permits some general conclusions:
    1. The forms in question have the same genesis, there is no casual convergence of forms. It would be convenient to term them as forms of the salt-, gypsum-, and carbonate karst. There is no justification for a fundamental distinction between the “karstification” of limestone and the “leaching” of gypsum and salt.
    2. The different liability to karstification (Karstgunst) of rocks can be compensated by a different liability to karstification due to climatic factors.
    3. Similarly the other factors of karstification vary gradually; they add up or compensate each other. A classification of climatic-morphological karst provinces seems to be possible only by means of analysis and balance of the single factors and their effects.
      相似文献   

    13.
    Anisian to Ladinian sedimentary rocks of the Northern Calcareous Alps from the area between the Arlberg pass and the Kaisergebirge mountains have been sampled (more than 2500 samples) in about 50 stratigraphic profiles, recorded in great detail. The (silicate) mineral residue, fraction below 2 micron, resulting from solution in formic acid, has been investigated mineralogically. Its sheet silicate content proved to be markedly homogeneous, containing mainly di-octahedral illite minerals, their crystallinity as most prominent result found to increase in a twofold way:
    1. The (Upper Austro-Alpine) Lechtal-Nappe is in its southern part characterized by increasing illite crystallinity from hanging to basal strata within the Ladinian to Anisian stratigraphic column. The source of this effect is found to be older than folding was.
    2. The whole area of sedimentary rocks investigated here presents an increase in illite crystallinity data from north to south (i. e. towards the Central Alpine metamorphic units), irrespective of the presently existing tectonic structures (folding or nappe units within the Upper Austro-Alpine of the Northern Calcareous Alps). Hence the source of this effect must be younger than these events were. With this also a broad margin of “anchimetamorphic” influence has been detected within the southern part of the Northern Calcareous Alps, in the area of the Mieminger and Wetterstein mountains showing even a strong extension towards the north (reaching the location of Garmisch-Partenkirchen)
    . These effects can by no means be attributed simply to sedimentary mineral distribution. Contradictionary to such an interpretation are the non-conformity of the illite crystallinity distribution within the existing tectonic setting to the original sedimentary position as well as general sedimentary data (paleo-morphology within the sedimentation area compared to homogeneous mineral distribution). Also (former or recent) sedimentary overburden cannot be quoted for as explanation, with no indication for this influence found so far in the stratigraphie profiles investigated at the thick Triassic sedimentary rock sequence in the steep descent of the Southern Karwendel mountains as well as in more than 6400 m of sedimentary rock sequence investigated in the ultradeep exploration borehole Vorderriß 1. The effects described here are attributed to very low grade metamorphic (“anchimetamorphic”) influences detected by these investigations within the Northern Calcareous Alps. A much higher influence due to increase in temperature compared to increase of pressure is indicated by experimental work done by the author. Even with a cautious attempt to incorporate these newly found temperature effects on Triassic sedimentary rocks into the geologic development of the Northern Calcareous Alps and the Alpine Orogeny, at least for the older effect the conception of “transported” metamorphism is implied, perhaps also for the younger one. This idea is furthermore supported by K/Ar — age determinations of well ordered illite minerals gained from the Schwaz Triassic occurrence, yielding data of about 110–120 mio. y. This age for the older temperature effect can be explained in terms of (starting?) subduction of Penninic units below Austro-Alpine units, long before Austro-Alpine nappes reached their present position within the Northern Calcareous Alps.  相似文献   

    14.
    三叠纪海的硫同位素   总被引:10,自引:0,他引:10       下载免费PDF全文
    前言自Ault和Kulp(1959)发表第一批海相硫酸盐岩的硫同位素分析数据以来,海相硫酸盐岩(石膏、硬石膏)的硫同位素研究工作已进行了二十余年。  相似文献   

    15.
    Mn-activated cathodoluminescence can be used in several fields of carbonate petrography. It may, for instance, be possible to recognize
    1. cement sequences and their correlation (Tab. 1, Figs. 1, 2, 4; Tab. 2, Fig. 1)
    2. growth fabrics of skeletons (Tab. 2, Figs. 2, 3, 4; Tab. 3, Figs. 1, 2)
    3. dolomitisation processes and problems (Tab. 1, Figs. 1, 2; Tab. 4, Fig. 2)
    4. transformation paths from Mg-calcite to calcite and from aragonite to calcite (Tab. 2, Fig. 1; Tab. 3, Figs. 3, 4; Tab. 4, Fig. 1)
    5. growth structures in certain types of ooids (Tab. 1, Fig. 4; Tab. 3, Fig. 3; Tab. 4, Fig. 1)
    6. reworked skeletal particles (Tab. 3, Fig. 4)
    7. phantom grains and fossil-outlines in a micro- or macrocrystalline groundmass (Tab. 4, Figs. 2, 3)
    8. healed fissures crossing micro- or macrocrystalline carbonate rocks (Tab. 4, Fig. 4).
    These are, however, no general luminescence criteria indicating the depositional environment. Luminescence of calcite and dolomite requires 20–40 ppm Mn, with the equipments used in this study. Aragonite is not yet investigated systematically. Zonal luminescence in carbonate cements may indicate changes of the chemical composition of the aquifer and may be used for “cement stratigraphy”. In skeletons it rather indicates physiological changes. While aragonitic skeletons lose their luminescence Zonation during replacement by calcite, Mg-calcite skeletons may keep parts of it, because their replacement preserves the original crystal fabric. Blotchy luminescence developes in Mg-calcitic particles during their adjustment to lower Mg-calcites by dissolution-precipitation processes in solutions with changing Mn/Fe-ratios.  相似文献   

    16.
    Based on distinctive stratigraphic and/or structural characteristics, the Brazilian continental margin can be divided into two main provinces:
    1. The southeastern-eastern province, extending from the Pelotas to the Recife-João Pessoa Basin, presents a tensional tectonic style of Late Jurassic-Early Cretaceous age, paralleling the structural alignements of the Precambrian basement, except in the north-eastern segment where the Mesozoic faults of the Recife-João Pessoa Basin cut across the east-west basement directions. The basin-fill, Upper Jurassic through Recent, consists, where complete, of three stratigraphic sequences, each of a distinct depositional environment: (a) a lower clastic non-marine sequence; (b) a middle evaporitic sequence, and (c) an upper clastic paralic and open marine sequence.
    2. The northern province, extending from the Potiguar Basin to the Amazon Submarine Basin, displays both tensional and compressional tectonic styles of Upper Jurassic (?) to Upper Cretaceous age either paralleling or cutting transversally the basement alignments. The stratigraphic column differs from the southeastern-eastern province in lacking the Lower Cretaceous evaporitic rocks.
    The integration of the stratigraphie and structural data allows one to determine in the eastern Brazilian marginal basins the main evolutionary stages of a typical pull-apart continental margin: a continental pre-rift and rift stage, an evaporitic proto-ocean stage, and a normal marine open ocean stage. In the northern province it is possible to infer a continental rift-valley-stage, a transform stage and an open continental-margin stage. The relationship between the rift-valley and the transform stages is yet not clear.  相似文献   

    17.
    本文描述的双壳类化石共5属13种,分别采自喀喇昆仑山地区9个地点,分别采目下三叠统下河尾滩群、中三叠统上河尾滩群、上三叠统克勒青河组.所描述的该区化石绝大多数为首次报道.早三叠世双壳类动物群无疑地属于南特提斯区,中晚三叠世的双壳类及沉积具有浊流沉积特征,并根据构造研究结果,处于南特提斯区.  相似文献   

    18.
    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).
    This coherent overturned sequence can be observed from the St-Niklaus area to the Moosalp pass to the north. Detailed mapping revealed that the St-Niklaus syncline is symmetrical and connects the overturned limb of the Siviez-Mischabel nappe to the normal series of the Upper Stalden zone. U-Pb zircon geochronology on magmatic and detrital zircons allowed constraining ages of these formations. Detrital zircons display ages ranging from 2900 ± 50 to 520 ± 4 Ma in the Törbel Formation, and from 514 ± 6 to 292 ± 9 Ma in the Moosalp Formation. In addition, the Permian Randa orthogneiss is intrusive into the polymetamorphic gneisses and into the Permo-Carboniferous metasediments of the overturned limb of the Siviez-Mischabel nappe. This revision clarified also the lithostratigraphy of the nearby and subjacent Lower Stalden zone composed of an overturned limb with Permo-Carboniferous formations. This has critical implications for the tectonic setting of the nappes in the region, speaking for few recumbent folds with well preserved normal and overturned limbs instead of a succession of imbricate thrust sheets in a normal stratigraphic position.  相似文献   

    19.
    铁矿赋存于上三叠统石钟山组下段底部和中部,属沉积成因的海陆交互—湖相铁矿床.铁矿床的水平分带现象明显,自东而西:紫红色泥岩→褐铁矿→菱铁矿→黄铁矿.  相似文献   

    20.
    Continuous shallow marine carbonates spanning the Triassic–Jurassic boundary are exposed in the Karaburun Peninsula, Western Turkey. The studied section (Tahtaiskele section) consists of Upper Triassic cyclic shallow marine carbonates intercalated with clastics overlain by Lower Liassic carbonates. Based on the microfacies stacking patterns, three main types of shallowing-upward cycles have been recognized. Cycles are mostly composed of subtidal facies at the bottom, intertidal/supratidal facies and/or subaerial exposure structures at the top. The duration of the cycles suggests that cycles were driven by the precessional Milankovitch rhytmicity. In the sequence stratigraphic frame of the Tahtaiskele section 4 sequence boundaries were detected and globally correlated. The first sequence boundary is located at the Alaunian–Sevatian boundary nearly coinciding with the first appearance of Triasina hantkeni. The second falls in the Rhaetian corresponding to a major sea level fall which led to the invasion of forced regressive siliciclastic deposits over the peritidal carbonates. The third occurs close to the T/J boundary and the fourth lies slightly above the base of the Jurassic. In the studied section, extinction, survival and recovery intervals have been recognized based on the stratigraphic occurrence patterns of benthic foraminifera and algae. Foraminifers became nearly totally extinct in the inner carbonate shelves at the Triassic–Jurassic boundary and an interval of approximately 0.5 my passed before the begining of the recovery of Jurassic foraminifera.  相似文献   

    设为首页 | 免责声明 | 关于勤云 | 加入收藏

    Copyright©北京勤云科技发展有限公司  京ICP备09084417号