The late Palaeozoic Gondwana glaciation

The glacial deposits of Gondwana are today spread over one whole hemisphere. On the re-assembled Gondwana continents they still occupy an area exceeding that of the Pleistocene glaciation. The onset of the glaciation in the different areas has not yet been dated satisfactorily. The earliest lower and middle Carboniferous glacial beds occur in the Andean belt and in eastern Australia, where high mountains may have existed at that time. During Stephanian-Sakmarian time, when the pole wandered over Antarctica, large ice sheets reached sealevel in all the major depositories. Palaeotopographical reconstructions allow the conclusion that some of the ice centres were supported by uplands which reached altitudes of up to 1,500 m above sealevel. Depending on their palaeotopographical positions the glacigenic sediments exhibit the full facies range to be expected between glaciated uplands and glaciomarine environments. There are indications that ice may have flowed from Africa into the Paraná Basin, and from Antarctica into the Great Karoo-Basin and into Australia. At least 12 advances and retreats have been recognized in the Paraná Basin. Closer to the ice centres the record is less complete. The retreats were probably more of an interstadial than an interglacial nature. There is some evidence that the final deglaciation proceeded in stages from South America over Africa to Antarctica. The ice centres were fed by moist air from the Pacific Ocean and the Tethys.

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Zusammenfassung Die glazialen Ablagerungen von Gondwana sind heute über eine ganze Hemisphäre verteilt. Auch auf dem rekonstruierten Gondwana nehmen sie noch ein Gebiet ein, welches das der pleistozänen Vereisung übertrifft. Die frühesten, unter- und mittelkarbonen Vereisungsspuren finden sich im Anden-Gürtel und im Tasman-Belt in Ostaustralien, wo zu dieser Zeit hohe Gebirgsketten existiert haben können. Während des Stephan und Sakmar, als der Pol sich auf der Antarktis befand, erreichten große Inlandeis-Decken den Seespiegel in allen größeren Ablagerungsbecken. Paläotopographische Rekonstruktionen erlauben die Schlußfolgerung, daß einige der Eiszentren sich auf Hochländern mit Höhen von bis zu 1500 m befanden. Die glazialen Sedimente zeigen, abhängig von ihrer paläotopographischen Position, alle zu erwartenden Faziestypen. Es gibt Hinweise, daß Eis von Afrika in das Paraná-Becken und von Antarktika in das Große Karoo-Becken und nach Australien geflossen sein könnte, Wenigstens 12 Vorstöße und Rückzüge sind im Paraná-Becken erkannt worden. In der Nähe der Eiszentren ist die Zahl geringer. Die Rückzüge hatten wahrscheinlich mehr die Natur von Interstadialen als von Interglazialen. Es gibt Hinweise, daß das finale Abschmelzen im unteren Perm in mehreren Phasen von Südamerika über Afrika nach Antarktika fortgeschritten sein könnte. Die Eiszentren wurden durch feuchte Luftmassen vom Pazifischen Ozean und der Tethys genährt.

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Résumé Les dépôts glaciaires de Gondwana sont répartis actuellement sur une hémisphère entière. Même sur le Gondwana reconstitué, ils occupent encore une surface qui dépasse celle de la glaciation pleistocène. Les traces de glaciation les plus précoces, èo- et mésocarbonifères se trouvent dans la ceinture andine et dans la ceinture tasmanienne d'Australie orientale, où des chaînes de montagnes élevées ont pu exister à cette époque. Pendant le Stéphanien et le Sakmarien, lorsque le pôle s'est trouvé dans l'Antarctique, de grandes nappes continentales de glace ont atteint le niveau de la mer dans tous les grands bassins sédimentaires. Des reconstitutions paléotopographiques permettent de conclure que quelques-uns des centres de glaciation se trouvaient dans des zones de montagnes ayant des altitudes atteignant 1500 m. Les sédiments glaciaires montrent, en fonction de leur position paléotopographique, tous les types de faciès que l'on peut attendre. D'après certaines indications, la glace aurait pu couler d'Afrique dans le bassin du Paraná et de l'Antarctique dans le grand bassin du Karoo et vers l'Australie. Au moins douze avancées et retraits ont été reconnus dans le bassins du Paraná. A proximité des centres de glaciation leur nombre est moindre. Les retraits avaient sans doute un caractère plus interstadiaire qu'interglaciaire. Certaines indications permettent de penser que la fusion finale pouvrait avoir progressé, au cours du Permien inférieur, d'Amérique du Sud vers l'Afrique puis vers l'Antarctique, en plusieurs phases. Les centres de glaciation ont été nourris par des masses d'air humides venant de l'Ocean Pacifique et de la Téthys.

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Provenance of middle to late Palaeozoic sediments in the northeastern Colombian Andes: implications for Pangea reconstruction

ABSTRACT

Global-scale Palaeozoic plate tectonic reconstructions have suggested that Laurentia was obliquely approaching against the northwestern margin of Gondwana until the final agglutination of Pangea. In this contribution integrated petrographic analysis, heavy mineral analysis, and tourmaline geochemistry were done, and U–Pb detrital zircon geochronology was obtained, in late Palaeozoic sedimentary and meta-sedimentary units from the Floresta and Santander Massifs in the Eastern Colombian Andes in order to constrain their provenance and related it with the magmatic, sedimentary, and deformational record of the Gondwana–Laurentia convergence until the late Carboniferous to Permian formation of Pangea. Late Devonian to early Carboniferous sandstones from the Floresta Massif changed from sublithoarenites to lithoarenites, tracking the progressive uplift and unroofing of sedimentary and metamorphic rocks, with associated volcanic activity. The U–Pb detrital zircon geochronology from the sedimentary and metasedimentary of Floresta and Santander documents Mesoproterozoic and Palaeoproterozoic sources, and younger Ordovician to Silurian age populations, that can be related to the early to middle Palaeozoic plutonic rocks and the Amazon Craton. The limited Silurian to Early Devonian detrital ages that contrast with the more significant Middle to Late Devonian zircons that document the erosion of contemporaneous magmatic sources formed after a late Silurian to Early Devonian reduction on the magmatic activity along the proto-Andean margin. These rocks were apparently deformed and metamorphosed between the late Carboniferous and the early Permian. It is suggested that the filling and deformation record of these rocks documented the changes in plate convergence obliquity at the western margin of Gondwana associated with the migration of Laurentia until its final position in Pangea. Between the late Carboniferous and the early Permian, peri-Gondwanan continental terranes also collided with the continental margin. Over-imposed Mesozoic tectonics have contributed to the final redistribution of these terranes to their current position.

Abbreviations:LA: laser ablation inductively couple mass spectrometer; CL: cathodoluminiscence     

Gondwana fragments in the Eastern Alps: A travel story from U/Pb zircon data

We compare detrital U/Pb zircon age spectra of Carboniferous and Permian / Lower Triassic sedimentary rocks from different structural positions within the Austroalpine nappe pile with published ages of magmatic and metamorphic events in the Eastern Alps and the West Carpathians. Similarities between sink and possible sources are used to derive provenance of sediments and distinct frequency peaks in sink and source age pattern are used for paleogeographic plate tectonic reconstructions. From this, travel paths of Austroalpine and West Carpathian basement units are traced from the Late Neoproterozoic to the Jurassic. We place the ancestry of basement units on the northeastern Gondwana margin, next to Anatolia and the Iranian Luth-Tabas blocks. Late Cambrian rifting by retreat of the Cadomian Arc failed and continental slivers re-attached to Gondwana during a late Cambrian / early Ordovician orogenic event. In the Upper Ordovician crustal fragments of the Galatian superterrane rifted off Gondwana through retreat of the Rheic subduction. An Eo-Variscan orogenic event at ~390 Ma in the Austroalpine developed on the northern rim of Galatia, simultaneously with a passive margin evolution to the south of it. The climax of Variscan orogeny occurred already during a Meso-Variscan phase at ~350 Ma by double-sided subduction beneath Galatia fragments. The Neo-Variscan event at ~330 Ma was mild in eastern Austroalpine units. This orogenic phase was hot enough to deliver detrital white mica into adjacent basins but too cold to create significant volumes of magmatic or metamorphic zircon. Finally, the different zircon age spectra in today's adjacent Carboniferous to Lower Triassic sediments disprove original neighbourhood of basins. We propose lateral displacement of major Austroalpine and West-Carpathian units along transform faults transecting Apulia. The intracontinental transform system was released by opening of the Penninic Ocean and simultaneous closure of the Meliata Hallstatt Ocean as part of the Tethys.     

Evolution of the Proto-Tethys in the Baoshan block along the East Gondwana margin: constraints from early Palaeozoic magmatism

Zircon U–Pb ages and geochemical and isotopic data for Late Ordovician granites in the Baoshan Block reveal the early Palaeozoic tectonic evolution of the margin of East Gondwana. The granites are high-K, calc-alkaline, metaluminous to strongly peraluminous rocks with A/CNK values of 0.93–1.18, are enriched in SiO₂, K₂O, and Rb, and depleted in Nb, P, Ti, Eu, and heavy rare earth elements, which indicates the crystallization fractionation of the granitic magma. Zircon U–Pb dating indicates that they formed at ca. 445 Ma. High initial ⁸⁷Sr/⁸⁶Sr ratios of 0.719761–0.726754, negative ?_Nd(t) values of –6.6 to –8.3, and two-stage model ages of 1.52–1.64 Ga suggest a crustal origin, with the magmas derived from the partial melting of ancient metagreywacke at high temperature. A synthesis of data for the early Palaeozoic igneous rocks in the Baoshan Block and adjacent Tengchong Block indicates two stages of flare-up of granitic and mafic magmatism caused by different tectonic settings along the East Gondwana margin. Late Cambrian to Early Ordovician granitic rocks (ca. 490 Ma) were produced when underplated mafic magmas induced crustal melting along the margin of East Gondwana related to the break-off of subducted Proto-Tethyan oceanic slab. In addition, the cession of the mafic magmatism between late Cambrian-Early Ordovician and Late Ordovician could have been caused by the collision of the Baoshan Block and outward micro-continent along the margin of East Gondwana and crust and lithosphere thickening. The Late Ordovician granites in the Baoshan Block were produced in an extensional setting resulting from the delamination of an already thickened crust and lithospheric mantle followed by the injection of synchronous mafic magma.     

The evolution of illite to muscovite: mineralogical and isotopic data from the Glarus Alps,Switzerland

Thirty-five illite and muscovite concentrates were extracted from Triassic and Permian claystones, shales, slates and phyllites along a cross-section from the diagenetic Alpine foreland (Tabular Jura and borehole samples beneath the Molasse Basin) to the anchi- and epimetamorphic Helvetic Zone of the Central Alps. Concentrates and thin sections were investigated by microscopic, X-ray, infrared, Mössbauer, thermal (DTA and TG), wet chemical, electron microprobe, K-Ar, Rb-Sr, ⁴⁰Ar/³⁹Ar and stable isotope methods.With increasing metamorphic grade based on illite crystallinity data (XRD and IR) the following continuous changes are observed: (i) the 1Md2M₁ polymorph transformation is completed in the higher grade anchizone; (ii) K₂O increases from 6–8 wt. % (diagenetic zone) to 8.5–10% (anchizone) to 10–11.5% (epizone), reflecting an increase in the total negative layer charge from 1.2 to 2.0; (iii) a decrease of the chemical variation of the mica population with detrital muscovite surviving up to the anchizone/ epizone boundary; iv) a shift of an endothermic peak in differential thermal curves from 500 to 750° C; (v) K-Ar and Rb-Sr apparent ages of the fraction <2 m decrease from the diagenetic zone to the epizone, K-Ar ages being generally lower than Rb-Sr ages. The critical temperature for total Ar resetting is estimated to be 260±30° C. K-Ar and Rb-Sr ages become concordant when the anchizone/ epizone boundary is approached. The stable isotope data, on the other hand, show no change with metamorphic grade but are dependent on stratigraphic age.These results suggest that the prograde evolution from 1 Md illite to 2M₁ muscovite involves a continuous lattice restructuration without rupture of the tetrahedral and octahedral bonds and change of the hydroxyl radicals, however this is not a recrystallization process. This restructuration is completed approximately at the anchizone/epizone boundary. The isotopic data indicate significant diffusive loss of ⁴⁰Ar and ⁸⁷Sr prior to any observable lattice reorganization. The restructuration progressively introduces a consistent repartition of Ar and K in the mineral lattices and is outlined by the ⁴⁰Ar/³⁹Ar age spectra.Concordant K-Ar and Rb-Sr ages of around 35-30 Ma. with concomitant concordant ⁴⁰Ar/³⁹Ar release spectra are representative for the main phase of Alpine metamorphism (Calanda phase) in the Glarus Alps. A second age group between 25 and 20 Ma. can probably be attributed to movements along the Glarus thrust (Ruchi phase), while values down to 9 Ma., in regions with higher metamorphic conditions, suggest thermal conditions persisting at least until the middle Tortonian.     

Provenance of Palaeozoic sandstones from the Carnic Alps (Austria): petrographic and geochemical indicators

An integrated approach of petrographic analysis, whole rock geochemistry and microprobe analysis has been applied to obtain information on the geodynamic development and the provenance for Ordovician to Permian siliciclastic successions exposed within the Carnic Alps (Austria). Sandstone detrital mode and geochemical results refine previous geodynamic interpretations. Late Ordovician samples indicate a stable craton and recycled orogenic and, possible, extensional setting. The Early Carboniferous is interpreted to represent a compressional environment, followed by a Late Carboniferous molasse-type foreland basin, and a Permian extensional geodynamic setting. Contrasting geochemical patterns of post-Variscan and Permian sequences suggest a rift setting. Electron microprobe data of detrital white mica also indicate changes in the provenance. Compositional data reflect a shift from low- to medium-grade metamorphic (Ordovician) to high-grade metamorphic (Carboniferous) to low- to medium-grade metamorphic and plutonic source rocks (Permian). Additionally, our data show that various chemical discrimination diagrams do not include all possible ranges of sandstones, and that high contents of detrital mica and ultra-stable heavy minerals may cause misclassification. Consequently, we propose the use of multi-method approach for provenance studies, including the control of geochemical data by modal analysis and heavy mineral investigations.     

Neoproterozoic to Lower Palaeozoic successions of the Tandilia System in Argentina: implication for the palaeotectonic framework of southwest Gondwana

The Cryogenian to Uppermost Ediacaran successions of the Tandilia System (Sierras Bayas Group and Cerro Negro Formation) in central-eastern Argentina is exceptional because of its unmetamorphosed and nearly undeformed character, its sediment provenance trend and the absence of any identified glacial deposit and the deposition of warm water carbonates. We decipher a dramatic change in the basin evolution from small-scale depositional areas during the Neoproterozoic to a larger basin related to an active continental margin throughout the Uppermost Ediacaran. The base of the succession is represented by immature detritus of alkaline composition (Villa Mónica Formation), but towards the top of this formation, the material is sorted and reworked, nonetheless still reflecting in its detritus the local rocks. The clastic deposition is interrupted by diagenetic overprinted dolomites. The unconformable overlying quartz-arenitic Ediacaran Cerro Largo Formation reworked the Cryogenian Villa Mónica Formation and contains mainly felsic granitic and metamorphic basement material of slightly wider variety, while the dominant alkaline geochemical signature in rocks of the Villa Mónica Formation disappears. Based on diagenetic, petrographic and sedimentological data, we can interpret the unconformity representing a longer time of erosion. The Cerro Largo Formation shows a transition to mudstones and the heterolithic facies of the Olavarría Formation. The top of the Sierras Bayas Group is represented by limestones (Loma Negra Formation), which are discordantly overlain by the Uppermost Ediacaran Cerro Negro Formation. The latter displays detrital material derived from a continental arc, mafic and felsic sources. Several arc-related geochemical proxies (Th/Sc?<?0.8; Zr/Sc?<?10; La/Sc?<?2; Ti/Zr?>?20) are recorded in the sediment detritus, as are syn-depositional pyroclastites. The absence of volcanic material in the underlying rocks allows proposing that the Cerro Negro Formation is related to an active continental margin fringing Gondwana (??Terra Australis Orogen??) as a retro-arc or retro-arc foreland basin.     

The Early Palaeozoic break-up of northern Gondwana,new palaeomagnetic and geochronological data from the Saxothuringian Basin,Germany

Early Palaeozoic volcanic and sedimentary rocks from the Saxothuringian Basin (Franconian Forest, northern Bavaria) have been subjected to detailed radiometric and palaeomagnetic studies in order to determine the tectonic environment and geographic setting in which they were deposited. Two hand samples were collected from the as yet undated pyroclastic flow deposits for ²⁰⁷Pb/²⁰⁶Pb age dating. Radiometric results for these samples, obtained by the single-zircon evaporation technique, are identical within error, and the mean age of all measured grains is 478.2ǃ.8 Ma (n=11). This age is considered to be primary and firmly constrains the eruption of the ignimbrites and formation of the subaqueous pyroclastic flows as having occurred in Early Ordovician (Arenig) times. Palaeomagnetic studies were carried out on these Early Ordovician volcanic rocks, and also on the biostratigraphically dated, Late Ordovician (Ashgillian) Döbra sandstones. The volcanic rocks carry up to three directions of magnetisation. The poorly defined, low and intermediate unblocking temperature directions are thought to represent secondary overprint directions of post-Ordovician age. The high temperature component, however, identified at temperatures of up to 580 °C, is of mixed polarity and passes the fold test with 99% confidence. The overall mean direction after bedding correction is 189°/76°, !₉₅=11.6°, k=44.7 (25 samples, five sites), and is considered to be primary and Early Ordovician in origin. It yields a palaeo-south pole at 24°N and 007°E, which translates into palaeolatitudes of 63°+21.7°/-17.3° S for the Saxothuringian Terrane. Samples from the Late Ordovician Döbra sandstone are generally very weakly magnetised. A high temperature D component of magnetisation can be identified in some samples and yields a mean direction of 030°/-58°, !₉₅=18.5°, k=25.7 (15 samples, four sites) after bedding correction. The Arenig palaeomagnetic results indicate high palaeolatitudes, but separation from northern Gondwana. This is in basic agreement with data from elsewhere in the Armorican Terrane Assemblage, all of which suggest high southerly palaeolatitudes in the Early Ordovician. The geochemical signatures of these rocks indicate emplacement in an extensional environment. These new data, therefore, are interpreted as marking the onset of rifting of Saxothuringia from the north African margin of Gondwana, and the start of the relative northward migration of the Saxothuringian Terrane. Although the Late Ordovician palaeomagnetic results presented here are only poorly constrained, they suggest an intermediate palaeolatitude for Saxothuringia in Ashgillian times, in good agreement with Late Ordovician palaeomagnetic data from the Barrandian.     

Palaeozoic corals: their evolution and palaeoecology

In recent years, our understanding of Palaeozoic corals has increased enormously. Several new groups have been discovered, extending the range of corals back to the early Cambrian, and we now have a clearer idea of the relationships between them. None of them was a direct ancestor to the post‐Palaeozoic corals. Similarly, the ecology of Palaeozoic corals differed from that of their living relatives in important respects. Palaeozoic corals were principally adapted for life on soft substrates and were not the spectacular reef‐builders that modern corals have become. However, their contribution to Palaeozoic ecosystems is nonetheless fascinating. Their structural adaptations and growth‐forms can tell us much about life and processes on Palaeozoic sea floors.     

Palaeozoic to Early Jurassic history of the northwestern corner of Gondwana,and implications for the evolution of the Iapetus,Rheic and Pacific Oceans

The Palaeozoic to Mesozoic igneous and metamorphic basement rocks exposed in the Mérida Andes of Venezuela and the Santander Massif of Colombia are generally considered to define allochthonous terranes that accreted to the margin of Gondwana during the Ordovician and the Carboniferous. However, terrane sutures have not been identified and there are no published isotopic data that support the existence of separate crustal domains. A general paucity of geochronological data led to published tectonic reconstructions for the evolution of the northwestern corner of Gondwana that do not account for the magmatic and metamorphic histories of the basement rocks of the Mérida Andes and the Santander Massif. We present new zircon U–Pb (ICP-MS) data from 52 igneous and metamorphic rocks, which we combine with whole rock geochemical and Pb isotopic data to constrain the tectonic history of the Precambrian to Mesozoic basement of the Mérida Andes and the Santander Massif. These data show that the basement rocks of these massifs are autochthonous to Gondwana and share a similar tectono-magmatic history with the Gondwanan margin of Peru, Chile and Argentina, which evolved during the subduction of oceanic lithosphere of the Iapetus Ocean. The oldest Palaeozoic arc magmatism is recorded at ~ 500 Ma, and was followed shortly by Barrovian metamorphism. Peak metamorphic conditions at upper amphibolite facies are recorded by anatexis at ~ 477 Ma and the intrusion of synkinematic granitoids until ~ 472 Ma. Subsequent retrogression resulted from localised back-arc or intra-arc extension at ~ 453 Ma, when volcanic tuffs and interfingered sedimentary rocks were deposited over the amphibolite facies basement. Continental arc magmatism dwindled after ~ 430 Ma and terminated at ~ 415 Ma, coevally with most of the western margin of Gondwana. After Pangaea amalgamation in the Late Carboniferous to Early Permian, a magmatic arc developed on its western margin at ~ 294 Ma as a result of subduction of oceanic crust of the palaeo-Pacific ocean. Intermittent arc magmatism recorded between ~ 294 and ~ 225 Ma was followed by the onset of the Andean subduction cycle at ~ 213 Ma, in an extensional regime. Extension was accompanied by slab roll-back which led to the migration of the arc axis into the Central Cordillera of Colombia in the Early Jurassic.     

Lower Palaeozoic volcanism of the Eastern Alps and its geodynamic implications

A geodynamic model for the lower Palaeozoic evolution of the Eastern Alps (upper Ordovician to middle Devonian; Gurktal Nappe, Styrian Greywacke Zone, Palaeozoic of Graz) is discussed, based on new field work and numerous geochemical analyses of volcanic rocks. It is suggested that in the upper Ordovician there existed on the one hand a passive continental margin or continental rift flooded by the sea, where mildly-alkaline basalts erupted (Magdalensberg-Series/Carinthia; Kaser-Series/Gurktaler Alpen). On the other hand, a convergent plate boundary in the form of an active continental margin or island arc or in the form of an orogen formed by continent-continent collision which can be recognized by the eruption of calc-alkaline volcanic rocks, probably also existed in the upper Ordovician (Blasseneck »Porphyroid«/Styrian Greywacke Zone; NockSeries/Gurktaler Alpen). In the lower Silurian a reorganization of the plate boundaries took place, resulting in the disintegration of the upper Ordovician collision zone along deep-reaching faults. Further extensional movements during the Silurian and Devonian led to the disintegration of a broad shelf platform and to the eruption of alkaline within-plate basalts. The extensional movements were responsible for the thinning of the continental crust and a general subsidence, which probably lasted until Lower Carboniferous time.

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Zusammenfassung Für das Alt-Paläozoikum der Ostalpen (oberes Ordoviz bis Mittel-Devon; Gurktaler Decke, Steirische Grauwak-kenzone, Grazer Paläozoikum) wird ein geodynamisches Modell diskutiert, das sich auf neue Kartierergebmsse und zahlreiche geochemische Analysen von Vulkaniten stützt. Es wird angenommen, daß im oberen Ordovizium einerseits ein passiver Kontinentalrand oder ein vom Meer überflutetes kontinentales Dehnungsfeld bestand, in welchem schwachalkalische Intraplattenbasalte gefördert wurden (Magdalensberg-Serie/Kärnten; Kaser-Serie/Gurktaler Alpen). Andererseits existierte im oberen Ordovizium wahrscheinlich auch eine konvergierende Plattengrenze in Form eines aktiven Kontinentalrandes oder Inselbogens oder m Form eines durch Kontinent-Kontinent-Kollision entstandenen Orogens, welche sich durch die Förderung kalkalkalischer Vulkanite bemerkbar machte (Blasseneck-»Porphyroid«/Steirische Grauwackenzone; Nock-Serie/Gurktaler Alpen). Im unteren Silur kam es zu einer Reorganisation der Plattengrenzen, in deren Folge die oberordovizische Kollisionszone an tiefreichenden Störungen zerbrach. Weitere Dehnungsbewegungen führten im Silur und Devon zur Zerbrechung einer breiten Schelfplattform und zur Förderung von alkalischen Intraplatten-Basalten. Die Dehnungsbewegungen waren für eine Ausdünnung der kontinentalen Kruste und eine damit verbundene generelle Absenkung der Sedimentations-Becken verantwortlich, die wahrscheinlich bis zum Unterkarbon anhielt.

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Résumé L'auteur présente un modèle géodynamique relatif au Paléozoïque inférieur des Alpes orientales (Ordovicien supérieur à Dévonien moyen; nappe de Gurktal, Zone des Grauwackes de la Styrie, Paléozoïque de Graz). Ce modèle se base sur de nouvelles investigations de terrain et sur un grand nombre d'analyses géochimiques de roches volcaniques. Il propose l'existence pendant l'Ordovien supérieur:- d'une part d'une marge continentale passive ou d'une zone de distension continentale submergée accompagnée d'émission de basaltes intraplaques faiblement alcalins (série du Magdalensberg/Carinthie; Série du Kaser/Gurktaler Alpen);- d'autre part d'une limite de plaques convergentes qui revêt la forme d'une marge continentale active, ou d'un arc insulaire, ou d'un orogène formé par une collision continent-continent, comme en témoigne l'éruption de roches volcaniques calco-alcalines à l'Ordovicien supérieur (»Porphyroïd« du Blasseneck/Zone des Grauwackes de la Styrie; Série du Nock/Gurktaler Alpen). Pendant le Silurien inférieur, les limites de plaques sont réorganisées, entraînant la désintégration de la zone de collision ordovicienne le long de fractures profondes. De nouveaux mouvements distensifs au cours du Silurien et du Dévonien mènent à la désintégration d'une vaste plateforme continentale et à l'éruption de basaltes alcalins intraplaques. Les mouvements distensifs sont responsables d'un amincissement de la crôute continentale et d'une subsidence généralisée qui ont probablement duré jusqu'au Carbonifère inférieur.

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Accretion of juvenile crust at the Early Palaeozoic Antarctic margin of Gondwana: geochemical and geochronological evidence from granulite xenoliths

Geodynamic models for the Antarctic sector of the active Early Palaeozoic Palaeo-Pacific margin of Gondwana are based on the nature and age of the deep crust of the Robertson Bay terrane, the outermost lithotectonic unit of the margin. As this crustal block is covered with thick turbidite deposits, the only way to probe the deep crust is through the analysis of granulite xenoliths from Cenozoic scoria cones. Low-K felsic xenoliths yield the oldest (Middle Cambrian) laser-probe U–Pb ages on zircon areas with igneous growth zoning. This finding, along with the positive whole-rock ε_Nd(500Ma), suggests that these felsic rocks derived from a juvenile magma formed during the Early Palaeozoic Ross orogenic cycle. Mafic xenoliths have geochemical-isotopic compositions similar to those of modern primitive island arcs, suggesting the involvement of subducted oceanic crust in their magma genesis and accretion of juvenile crust at the Antarctic margin of Gondwana.     

From Middle Jurassic heating to Neogene cooling: The thermochronological evolution of the southern Alps

The Dolomite region is located in the Southern Alps, which were affected by Mesozoic extensional tectonics and by consequent thermal perturbations. In this work, vitrinite reflectance and apatite fission-track analysis are used to estimate the thermal evolution. These methodologies have been applied to the Permo-Mesozoic succession, which crops out along the TRANSALP seismic profile. The regional distribution of the organic matter maturity seems to be mainly controlled by different burials reached during the Norian-Liassic extensional phase, in connection with high heat flow values. The best solutions obtained from thermal modelling of both vitrinite and fission-track data suggest that peak of high heat flow occurred during Bajocian–Bathonian ages, when western Tethys was characterized by intrusions of gabbros and plagiogranites and extrusion of tholeiite basalts. This time coincides with the onset of the drifting phase and related thermal subsidence. The following thermal relaxation occurred during continuous sedimentation and the maximum burial does not coincide with peak temperatures. Cooling history has been carefully analysed through apatite fission-track data on samples collected close to the Valsugana overthrust, which document an important exhumation event at about 10 Ma. The related erosion has been analysed through the combined use of arenite petrography and fission-track analysis on detrital samples of the Veneto foredeep succession, which represents the storage of detritus during Tertiary. These data confirm that after Serravalian the Southalpine domain and related covers were affected by subaerial erosion.     

Uranium-lead isotopic evidence from zircons for lower Palaeozoic tectonic activity in the Austroalpine Nappe,the Eastern Alps

U/Pb isotopic data for two zircon suites are presented:

1. a pre D ₁ tonalite gneiss gives an age of 443 ± ₁₆ ¹³ m.y.
2. a post D ₁ leucogranite gneiss gives 427 ± ₁₁ ¹⁰ m.y.

Both zircon suites contain a minor inherited pre-Cambrian component. The data confirm a lower Palaeozoic age for the major, fabric-forming D ₁ event. Hercynian metamorphism which was sufficient to reset muscovite K/Ar ages to ca. 290 m.y. had little effect on the zircons. The possible importance of lower Palaeozoic orogeny in southern Europe and the uncertainties in regional palaeogeography are emphasised.     

Subduction,mega-shear systems and Late Palaeozoic basin development in the African segment of Gondwana

 Basins within the African sector of Gondwana contain a Late Palaeozoic to Early Mesozoic Gondwana sequence unconformably overlying Precambrian basement in the interior and mid-Palaeozoic strata along the palaeo-Pacific margin. Small sea-board Pacific basins form an exception in having a Carboniferous to Early Permian fill overlying Devonian metasediments and intrusives. The Late Palaeozoic geographic and tectonic changes in the region followed four well-defined consecutive events which can also be traced outside the study area. During the Late Devonian to Early Carboniferous period (up to 330 Ma) accretion of microplates along the Patagonian margin of Gondwana resulted in the evolution of the Pacific basins. Thermal uplift of the Gondwana crust and extensive erosion causing a break in the stratigraphic record characterised the period between 300 and 330 Ma. At the end of this period the Gondwana Ice Sheet was well established over the uplands. The period 260–300 Ma evidenced the release of the Gondwana heat and thermal subsidence caused widespread basin formation. Late Carboniferous transpressive strike-slip basins (e.g. Sierra Australes/Colorado, Karoo-Falklands, Ellsworth-Central Transantarctic Mountains) in which thick glacial deposits accumulated, formed inboard of the palaeo-Pacific margin. In the continental interior the formation of Zambesi-type rift and extensional strike-slip basins were controlled by large mega-shear systems, whereas rare intracratonic thermal subsidence basins formed locally. In the Late Permian the tectonic regime changed to compressional largely due to northwest-directed subduction along the palaeo-Pacific margin. The orogenic cycle between 240 and 260 Ma resulted in the formation of the Gondwana fold belt and overall north–south crustal shortening with strike-slip motions and regional uplift within the interior. The Gondwana fold belt developed along a probable weak crustal zone wedged in between the cratons and an overthickened marginal crustal belt subject to dextral transpressive motions. Associated with the orogenic cycle was the formation of mega-shear systems one of which (Falklands-East Africa-Tethys shear) split the supercontinent in the Permo-Triassic into a West and an East Gondwana. By a slight clockwise rotation of East Gondwana a supradetachment basin formed along the Tethyan margin and northward displacement of Madagascar, West Falkland and the Gondwana fold belt occurred relative to a southward motion of Africa. Received: 2 October 1995 / Accepted: 28 May 1996     

Late Palaeozoic to Triassic evolution of the Turan and Scythian platforms: The pre-history of the Palaeo-Tethyan closure

A number of en échelon-arranged, southwest-facing arc fragments of Palaeozoic to Jurassic ages, sandwiched between two fairly straight east-northeast trending boundaries, constitute the basement of the Scythian and the Turan platforms located between the Laurasian and Tethyside units. They have until now largely escaped detection owing to extensive Jurassic and younger cover and the inaccessibility of the subsurface data to the international geological community. These units are separated from one another by linear/gently-curved faults of great length and steep dip. Those that are exposed show evidence of strike-slip motion. The arc units originally constituted parts of a single “Silk Road Arc” located somewhere south of the present-day central Asia for much of the Palaeozoic, although by the late Carboniferous they had been united into a continental margin arc south of the Tarim basin and equivalent units to the west and east. They were stacked into their present places in northern Afghanistan, Turkmenistan, Caucasus and the northern Black Sea by large-scale, right-lateral strike-slip coastwise transport along arc-slicing and arc-shaving strike-slip faults in the Triassic and medial Jurassic simultaneously with the subductive elimination of Palaeo-Tethys. This gigantic dextral zone (“the Silk Road transpression”) was a trans-Eurasian structure and was active simultaneously with another, similar system, the Gornostaev keirogen and greatly distorted Eurasia. The late Palaeozoic to Jurassic internal deformation of the Dniepr–Donets aulacogen was also a part of the dextral strain in southern Europe. When the emplacement of the Scythian and Turan units was completed, the elimination of Palaeo-Tethys had also ended and Neo-Tethyan arcs were constructed atop their ruins, mostly across their southern parts. The western end of the great dextral zone that emplaced the Turan and Scythian units horsetails just east of north Dobrudja and a small component goes along the Tornquist–Teisseyre lineament.