Brittle basement deformation during the Caledonian Orogeny observed by K‐Ar geochronology of illite‐bearing fault gouge in west‐central Sweden

This study presents K-Ar ages of illite from fault gouges in crystalline basement in centralwestern Sweden. Samples were taken from two faults that localized brittle deformation marginal to and within mafic dikes that intruded Paleoproterozoic granitoids. K-Ar ages from ten separated grain fractions span from 823 to 392 Ma. Older ages obtained (823 to 477 Ma) were influenced by a mixture of illite and K-feldspar; the latter likely formed during a hydrothermal event prior to faulting. The remaining ages (442.1±9.7 to 391.7±6.1 Ma) were obtained from fractions from both faults hosting only authigenic illite, and show that illite crystallized during the Scandian Caledonian orogeny. These results indicate that previously presumed autochthonous Caledonian basement was involved in continental contraction and subsequent collapse of the Caledonian orogen, influencing both the mode and depth of penetration of deformation into Baltica

Formation et réactivation du système de rift pyrénéo-cantabrique : héritage, segmentation et évolution thermique

This study aims to describe the role of rift-inheritance and segmentation for reactivation and to investigate the influence of asymmetric rifting on the syn-rift thermal evolution, using the Pyrenean-Cantabrian system as a natural laboratory. The study of the Pyrenean-Cantabrian junction discards the existence of a Pamplona transform fault between the two rift segments and argues for an accommodation zone where rift segments overlap north and south of the Basque massifs in relation with north-south direction of extension. During convergence, rift segmentation and the Triassic evaporite decoupling horizon controlled the reactivation and the local orogenic architecture. Finally, this study shows that asymmetric hyperextension is associated with asymmetric and diachronous thermal evolution, and highlights the importance of understanding the tectonic evolution to define the thermal architecture.Cette étude vise à décrire le rôle de l’héritage et de la segmentation associés au rifting pour la réactivation ainsi qu’à étudier l’importance de l’asymétrie tectonique sur l’évolution thermique syn-rift, en utilisant le système pyrénéo-cantabrique comme laboratoire naturel. L’étude de la jonction entre les segments pyrénéen et cantabrique infirme l’hypothèse d’une faille transformante de Pampelune et met en évidence une zone d’accommodation où les segments de rifts se propagent au nord et au sud des massifs basques, associée à une direction d’extension nord-sud. Lors de la convergence, cette segmentation et le niveau de découplage associé aux évaporites triasiques contrôlent fortement la réactivation ainsi que l’architecture orogénique locale. Enfin, cette étude démontre que l’asymétrie lors de l’hyper-étirement est associée à une évolution thermique asymétrique et diachrone, et souligne l’importance de l’évolution tectonique pour l’architecture thermique

Formation and reactivation of the Pyrenean-Cantabrian rift system : inheritance, segmentation and thermal evolution

Cette étude vise à décrire le rôle de l’héritage et de la segmentation associés au rifting pour la réactivation ainsi qu’à étudier l’importance de l’asymétrie tectonique sur l’évolution thermique syn-rift, en utilisant le système pyrénéo-cantabrique comme laboratoire naturel. L’étude de la jonction entre les segments pyrénéen et cantabrique infirme l’hypothèse d’une faille transformante de Pampelune et met en évidence une zone d’accommodation où les segments de rifts se propagent au nord et au sud des massifs basques, associée à une direction d’extension nord-sud. Lors de la convergence, cette segmentation et le niveau de découplage associé aux évaporites triasiques contrôlent fortement la réactivation ainsi que l’architecture orogénique locale. Enfin, cette étude démontre que l’asymétrie lors de l’hyper-étirement est associée à une évolution thermique asymétrique et diachrone, et souligne l’importance de l’évolution tectonique pour l’architecture thermique.This study aims to describe the role of rift-inheritance and segmentation for reactivation and to investigate the influence of asymmetric rifting on the syn-rift thermal evolution, using the Pyrenean-Cantabrian system as a natural laboratory. The study of the Pyrenean-Cantabrian junction discards the existence of a Pamplona transform fault between the two rift segments and argues for an accommodation zone where rift segments overlap north and south of the Basque massifs in relation with north-south direction of extension. During convergence, rift segmentation and the Triassic evaporite decoupling horizon controlled the reactivation and the local orogenic architecture. Finally, this study shows that asymmetric hyperextension is associated with asymmetric and diachronous thermal evolution, and highlights the importance of understanding the tectonic evolution to define the thermal architecture

Formation and reactivation of the Pyrenean-Cantabrian rift system : inheritance, segmentation and thermal evolution

Cette étude vise à décrire le rôle de l’héritage et de la segmentation associés au rifting pour la réactivation ainsi qu’à étudier l’importance de l’asymétrie tectonique sur l’évolution thermique syn-rift, en utilisant le système pyrénéo-cantabrique comme laboratoire naturel. L’étude de la jonction entre les segments pyrénéen et cantabrique infirme l’hypothèse d’une faille transformante de Pampelune et met en évidence une zone d’accommodation où les segments de rifts se propagent au nord et au sud des massifs basques, associée à une direction d’extension nord-sud. Lors de la convergence, cette segmentation et le niveau de découplage associé aux évaporites triasiques contrôlent fortement la réactivation ainsi que l’architecture orogénique locale. Enfin, cette étude démontre que l’asymétrie lors de l’hyper-étirement est associée à une évolution thermique asymétrique et diachrone, et souligne l’importance de l’évolution tectonique pour l’architecture thermique.This study aims to describe the role of rift-inheritance and segmentation for reactivation and to investigate the influence of asymmetric rifting on the syn-rift thermal evolution, using the Pyrenean-Cantabrian system as a natural laboratory. The study of the Pyrenean-Cantabrian junction discards the existence of a Pamplona transform fault between the two rift segments and argues for an accommodation zone where rift segments overlap north and south of the Basque massifs in relation with north-south direction of extension. During convergence, rift segmentation and the Triassic evaporite decoupling horizon controlled the reactivation and the local orogenic architecture. Finally, this study shows that asymmetric hyperextension is associated with asymmetric and diachronous thermal evolution, and highlights the importance of understanding the tectonic evolution to define the thermal architecture

Role of rift-inheritance and segmentation for orogenic evolution: example from the Pyrenean-Cantabrian system

The Basque-Cantabrian junction corresponds to an inverted rift accommodation zone at the limit between the former hyperextended Pyrenean and Cantabrian rift segments. The recognition of an inherited rift segment boundary allows to investigate the reactivation associated with large-scale rift segmentation in an orogenic system. We use criteria from published field observations and seismic data to propose a new map of rift domains for the Basque-Cantabrian junction. We also provide balanced cross-sections that allow to define the along-strike architecture associated with segmentation during rifting and subsequent Alpine reactivation. Based on these results, this study aims to characterize and identify reactivated and newly formed structures during inversion of two rift segments and its intermitted segment boundary. It also aims to describe the timing of thin-skinned and thick-skinned deformation associated with the inversion of segmented rift systems. During convergence, two phases have been recognized within the rift segment (eastern Mauléon basin). The Late Cretaceous to Paleocene underthrusting/subduction phase was mostly governed by thin-skinned deformation that reactivated the former hyperextended domains and the supra-salt sedimentary cover. The Eocene to Miocene collisional phase, controlled by thick-skinned deformation that took place once necking domains collided and formed an orogenic wedge. At the rift segment boundary, the underthrusting/subduction phase was already controlled by thick-skinned deformation due to the formation of shortcutting thrust faults at the termination of overlapping V-shaped rift segments. This led to the formation of a proto-wedge composed of the Basque massifs. We suggest that this proto-wedge is responsible for the preservation of pre-Alpine structures in the Basque massifs and for the emplacement of subcontinental mantle rocks at a crustal level beneath the western Mauléon basin. These results argue for a first order cylindrical orogenic architecture from the Central Pyrenean segment to the Cantabrian segment (up to the Santander transfer zone) despite rift segmentation. They also highlight the control of 3D rift-inheritance for the initial phase of orogenic evolution and for the local architecture of mountain belts

Supporting information for: Thermal evolution of asymmetric hyperextended magma-poor rift systems: results from numerical modelling and Pyrenean field observations

Supplementary material of "Thermal evolution..." publicatio

The role of extensional detachment systems in thinning the crust and exhuming granulites: analogies between the offshore Le Danois High and the onshore Labourd Massif in the Biscay/Pyrenean rifts

Large uncertainties remain about the architecture, timing and role of the structures responsible for high degrees of crustal thinning and the exhumation of mid-crustal granulites in the Pyrenean and Biscay rift systems. Both, the Le Danois High in the North Iberian margin and the Labourd Massif in the Western Pyrenees preserve evidence of extensional detachment faults and include exhumed granulites, which are locally reworked in syn-rift sediments. In this study, we compare the crustal structure and its link to the overlying sediments at the two sites based on the interpretation of high quality 2D seismic reflection profiles offshore and field observations and published geological cross-sections onshore. New reported seismic and field observations support that extensional detachment systems delineate the top basement in the Le Danois High and the Labourd Massif, advocating for a similar tectonic evolution. We propose that the Le Danois and North Mauléon extensional detachment systems were responsible for high degrees of crustal thinning and the exhumation of the pre-rift brittle-ductile transition and associated mid-crustal granulites during Aptian to Cenomanian extension, leading to the formation of the Le Danois and Labourd crustal tapers. Subsequently tilted and uplifted during the Alpine convergence, the two taper blocks lay at present in the hanging-wall of major Alpine thrusts. Their position at overlapping, en-echelon hyperextended rift segments at the end of rifting, and the occurrence of shortcutting structures at depth linking neighbouring rift segments can explain the preservation of the rift-related detachment systems. This study proposes for the first time analogies between the offshore Le Danois High and the onshore Labourd Massif and demonstrates the importance of extensional detachment systems in thinning the crust and exhuming mid-crustal granulites at the seafloor in the Biscay and Pyrenean rift systems during Aptian to Cenomanian extension

Supporting information for publication "Nature, origin and evolution of the Pyrenean-Cantabrian junction"

Supporting information for publication "Nature, origin and evolution of the Pyrenean-Cantabrian junction" (Tectonics, doi: 10.1029/2020TC006134). It includes one figure showing the distribution of the basinal vs. platform facies of the Upper Cenomanian sediments from the Mauléon and Basque-Cantabre basins.<br

Data underlying the publication: Nature, origin and evolution of the Pyrenean‐Cantabrian junction

Table of the structural dataset (bedding, cleavage) from the Basque Country (France, Spain), used for the publication "Nature, origin and evolution of the Pyrenean-Cantabrian junction" by Lescoutre et al. (Tectonics, doi: 10.1029/2020TC006134). The structural data contain information about the dip and orientation of the bedding and cleavage from the Paleozoic basement of the Basque massifs as well as the Upper Triassic to Cenozoic sedimentary cover of the Mauléon and Basque-Cantabrian basins. They aimed to determine the deformation of the basement and sedimentary rocks of the Western Pyrenees. These data have been acquired by R. Lescoutre during 2016-2019 field campaigns using the Clino Field software (Petex).<br

Supporting information for publication "Nature, origin and evolution of the Pyrenean-Cantabrian junction"

Supporting information for publication "Nature, origin and evolution of the Pyrenean-Cantabrian junction" (Tectonics, doi: 10.1029/2020TC006134). It includes one figure showing the distribution of the basinal vs. platform facies of the Upper Cenomanian sediments from the Mauléon and Basque-Cantabre basins.<br