Deformation mechanisms in a continental rift up to mantle exhumation. Field evidence from the western Betics, Spain

International audienceThe identification of the structures and deformation patterns in magma-poor continental rifted margins is essential to characterize the processes of continental lithosphere necking. Brittle faults, often termed mantle detachments, are believed to play an essential role in the rifting processes that lead to mantle exhumation. However, ductile shear zones in the deep crust and mantle are rarely identified and their mechanical role remains to be established. The western Betics (Southern Spain) provides an exceptional exposure of a strongly thinned continental lithosphere, formed in a supra-subduction setting during Oligocene-Lower Miocene. A full section of the entire crust and the upper part of the mantle is investigated. Variations in crustal thickness are used to quantify crustal stretching that may reach values larger than 2000% where the ductile crust almost disappear, defining a stage of hyper-stretching. Opposite senses of shear top-to-W and top-to-E are observed in two extensional shear zones located close to the crust-mantle boundary and along the brittle-ductile transition in the crust, respectively. At locations where the ductile crust almost disappears, concordant top-to-E-NE senses of shear are observed in both upper crust and serpentinized mantle. Late high-angle normal faults with ages of ca. 21 Ma or older (40Ar/39Ar on white mica) crosscut the previously hyper-stretched domain, involving both crust and mantle in tilted blocks. The western Betics exemplifies, probably better than any previous field example, the changes in deformation processes that accommodate the progressive necking of a continental lithosphere. Three successive steps can be identified: i/a mid-crustal shear zone and a crust-mantle shear zone, acting synchronously but with opposite senses of shear, accommodate ductile crust thinning and ascent of subcontinental mantle; ii/hyper-stretching localizes in the neck, leading to an almost disappearance of the ductile crust and bringing the upper crust in contact with the subcontinental mantle, each of them with their already acquired opposite senses of shear; and iii/high-angle normal faulting, cutting through the Moho, with related block tilting, ends the full exhumation of the mantle in the zone of localized stretching. The presence of a high strength sub-Moho mantle is responsible for the change in sense of shear with depth. Whereas mantle exhumation in the western Betics occurred in a backarc setting, this deformation pattern controlled by a high-strength layer at the top of the lithosphere mantle makes it directly comparable to most passive margins whose formation lead to mantle exhumation. This unique field analogue has therefore a strong potential for the seismic interpretation of the so-called “hyper-extended margins”

Inferences on the Mesozoic evolution of the North Aegean from the isotopic record of the Chalkidiki block

International audienceThe Chalkidiki block is a major domain in the North Aegean that, contrary to other domains in the region, largely escaped thermal perturbations during Tertiary extension. As a result, the Chalkidiki block is an ideal candidate to glean information related to the timing of Mesozoic thermal events using appropriate geochronological techniques. We have undertaken a laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) study (U-Th-Pb on monazites and U-Pb on zircons) coupled with 40Ar/39Ar dating on nine samples from various structural levels within the thrust system of the Chalkidiki block. The eastern, and structurally lower part of the system revealed a complete isotopic reset of Carboniferous – Early Triassic monazites coeval with partial monazite destruction, REE-mobilisation and formation of apatite-allanite-epidote coronas at ~ 132 Ma, a reaction that is commonly observed in amphibolite-facies rocks. These coronas formed after crystallisation of garnet (i.e., at T > 580 °C) and, in all probability, either close to the peak-temperature conditions (~ 620 °C) on a prograde path or during retrogression between the peak-temperature and the low-temperature boundary of the amphibolite facies. Cooling of these rocks and arrival at mid-crustal levels occurred at 95–100 Ma. By contrast, the western, and structurally uppermost part of the system went through the same event by 120–125 Ma. Further structural considerations with respect to medium-temperature geochronology data imply that syn-metamorphic thrusting must have ceased by early Late Cretaceous. We emphasize that, with the sole exception of the Chalkidiki block, no pre-45 Ma medium-temperature geochronology data are preserved in other North Aegean domains, a feature that is clearly related to the extension-induced thermal perturbation of the region during the Tertiary

Etude par la methode 39Ar-40Ar de la redistribution de l'argon dans les mineraux des socles anciens repris par l'orogenese alpine : application a la geochronologie des massifs de l'Argentera-Mercantour, du Mont-Rose et de la Grande-Kabylie

SIGLECNRS T 55219 / INIST-CNRS - Institut de l'Information Scientifique et TechniqueFRFranc

L' exhumation de la zone axiale des Pyrénées orientales (une approche thermo-chronologique multi-méthodes du rôle des failles)

MONTPELLIER-BU Sciences (341722106) / SudocSudocFranceF

Nouvelles données géochronologiques Ar/Ar, Rb/Sr et Sm/Nd sur les éclogites du Monviso et de Dora Maira (Alpes Occidentales).

International audienc

Coeval blueschist exhumation along thousands of kilometers: Implications for subduction channel processes

International audienceWe herein focus on understanding what controls the detachment and migration of oceanic crustal slices along subduction zones. We provide evidence for the coeval Middle to Late Cretaceous exhumation of oceanic blueschists in the same Neotethyan subduction zone, across more than 3000 km, from depths around 30-40 km, over a short time interval (similar to 25 Ma) compared to the duration of subduction (>100 Ma). We stress the importance of such a geodynamic process and suggest that this exhumation was promoted by a regional-scale change in the long-term interplate mechanical coupling. On the basis of geological and geophysical evidence, we propose that the upward migration of oceanic fragments in subduction zones is normally inhibited and only occurs discontinuously, as the subduction channel opens up in response to a major change in plate geodynamics, slab geometry and dynamics, mantle wedge and slab hydration, or a combination of these

Processus d'accrétion crustale et régimes thermiques dans le bouclier des Guyanes (signatures géochimiques et thermochronologiques au Transamazonien (2250-1950Ma))

Ce travail de thèse s'intéresse à l'événement transamazonien en Guyane Française. Le Transamazonien constitue l'événement géodynamique majeur structurant le bouclier des Guyanes entre 2.2 et 2.0 Ga. L'évolution de l'orogenèse transamazonienne est décrite en termes de croissance crustale, prenant en compte des processus de recyclage archéen ainsi que des processus d'accrétion juvénile et de réactivation thermotectonique au Paléoprotérozoïque. Notre travail axé sur une étude géochronologique (U-Pb et Ar/Ar) et une étude géochimique (éléments majeurs et éléments en trace) a permis de proposer un modèle d'évolution en quatre étapes : Une première étape avec la formation d'une croûte océanique juvénile à 2.2 Ga, une seconde étape de croissance crustale, avec la formation de série TTG entre 2.18 et 2.1Ga. Cette seconde étape présente une évolution du contexte de subduction générant les TTG, le résultat est la formation de magmas type sanukitoïdes . La troisième étape présente la formation de magmas calco-alcalins (2.1 à 2.08 Ga) résultant du refroidissement du contexte de subduction déjà initié lors de la seconde étape. Le stade final est caractérisé par la formation de granites d'anatexie crustale (2.1 à 2.06 Ga). Plus globalement, notre étude sur le Transamazonien s'intéresse à la question clé des domaines paléoprotérozoïques, qui est de définir quels types de processus étaient actifs à cette période ? Le Paléoprotérozoïque se situe à la transition entre la période archéenne dominée par des processus de croissance crustale dits archaïques et une période récente caractérisée par des processus de croissance crustale dits modernes .MONTPELLIER-BU Sciences (341722106) / SudocSudocFranceF

New age constraints on emplacement of the cevenol granitoids, south french massif central

International audienceDuring the development of the Variscan orogeny, large amounts of granitic melt were produced, giving rise to the intrusion of granitoids at different structural levels. Despite numerous studies, ages available from previous work on the Cevennes granites remain largely imprecise. In order to better constrain the age and emplacement mode of these granites, we have combined U-Pb dating on monazites and zircons and Ar-40/Ar-39 dating on biotites with petrological observations, major element chemical analysis and SEM zircon imaging on five samples from the Aigoual-St Guiral-Liron and Mont Lozere granitic massifs. The results revealed that granitic intrusions and cooling in Southern Cevennes occurred in a short time span at similar to 306 Ma after the main episode of regional metamorphism. Petrological and chemical data suggest that they result from a mixing between mantle-derived basic magmas (lamprophyres) and lower crust acid magmas. At a regional scale the production of these melts occurred at the end of crustal thickening induced by nappe stacking, at the same time as the late anatectic events recorded further north in the Velay dome and the granulite facies metamorphism recorded in metasedimentary granulite enclaves brought up by Tertiary volcanoes of the Velay area (Bournac)

Polyphase seismic faulting in the Ivrea zone (Italian Alps) revealed by Ar-40/Ar-39 dating of pseudotachylytes

International audienceP>Most fault-related pseudotachylytes in the Val Sesia area, Ivrea zone, NW Italian Alps, occur in two areas: near the Canavese Line in the Kinzigite Formation paragneisses and in an elongate belt in the Mafic Complex gabbros away from the Canavese Line. Ar-40/Ar-39 dating indicates that pseudotachylytes from the Kinzigite Formation were formed in the late Eocene, likely during the early stages of the collision between the NW corner of the Adriatic indenter and the European margin. Pseudotachylytes from the Mafic Complex were formed under a transpressive strain regime, as suggested by kinematic indicators, and yield Early Cretaceous (Albian) Ar-40/Ar-39 ages. Their formation is possibly related to shortening during the inception of the tectonic inversion of the Adriatic passive margin