Reconstruction of the Exhumed Mantle Across the North Iberian Margin by Crustal‐Scale 3‐D Gravity Inversion and Geological Cross Section

Pedrera, Antonio; García-Senz, Jesús; Ayala, C.; Ruíz-Constán, Ana; Rodrı́guez-Fernández, L.; Robador, Alejandro; Menéndez, L. González

doi:10.1002/2017tc004716

Cited by 69 publications

(123 citation statements)

References 78 publications

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“…It is noteworthy that Roca et al () and Tugend et al () already proposed that both the BCB and the Parentis basins on each side of the Landes High could have been formed by a north‐dipping low‐angle detachment fault above hyperthinned crust and exhumed mantle. More recently Pedrera et al () alternatively proposed a HE model with a south dipping low‐angle fault in the BCB.…”

Section: Discussionmentioning

confidence: 99%

“…This folding may be related to salt tectonics developed in the deepest part of the basin (Figure a), with the associated rimmed depocenters. Pre‐HE and syn‐HE sediments are affected by the syn‐HE salt tectonics that controlled the structural style and sedimentary sequence deposited above the Upper Triassic series (Keuper), as highlighted by thickness and facies variations (e.g., Bodego et al, ; Iriarte, ; Pedrera et al, ), and by the development of extensional folds (Martinez‐Torres, ). The salt tectonics resulted in the formation of salt ridges and diapirs, rim‐synclines, and minibasins.…”

Section: Discussionmentioning

confidence: 99%

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The Nappe des Marbres Unit of the Basque‐Cantabrian Basin: The Tectono‐thermal Evolution of a Fossil Hyperextended Rift Basin

et al. 2019

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The architecture of the Pyrenean‐Cantabrian belt results from the inversion of a series of former Cretaceous rift basins. A HT‐LP metamorphic event dated at 105 to 85 Ma ago is commonly associated with an Albo‐Cenomanian episode of hyperextension of the continental crust. This metamorphism is well known in the eastern Basque‐Cantabrian Basin within the Nappe des Marbres Unit (NMU) that is preserved from intense compressional deformation during the Pyrenean orogeny. Based on a structural study at the scale of the eastern Basque‐Cantabrian Basin and on a dense sampling for TRSCM estimates with the Raman spectroscopy of carbonaceous material (RSCM) method (Raman Spectrometry on Carbonaceous Material), we show following results: (1) the NMU has recorded two major phases of deformation, related to a localized extensional ductile foliation (S1) during the Cretaceous rifting and later by the regional N‐S shortening, recorded by a regional cleavage (S2) observed only in shale sediments. (2) The NMU is affected by early salt tectonics related to several diapirs and salt walls fed by the Upper Triassic evaporitic layer. (3) The NMU recorded maximum temperatures exceeding 550°C, which represent some of the highest temperatures along the Pyrenees. These new data demonstrate that there is no E‐W lateral metamorphic gradient across the belt and that hyperextension rifting occurred consistently within a high‐thermal regime; (4) metamorphic isograds are oblique in respect of the main structures, suggesting that the metamorphic event postdates most of the early salt‐related deformations prior to or coeval with early stages of rifting. As it represents one of the best preserved example of preorogenic hyperextended basin, the eastern Basque‐Cantabrian Basin record may be used regionally to better understand the rift to orogen evolution of the Pyrenean Internal Metamorphic Zone but also more generally as an analog of salt‐bearing hyperextended rift record.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

The Nappe des Marbres Unit of the Basque‐Cantabrian Basin: The Tectono‐thermal Evolution of a Fossil Hyperextended Rift Basin

et al. 2019

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“…Pedrera et al () presented a new tectonic model for the Basque‐Cantabrian Basin in the Pyrenean‐Cantabrian belt, based on a geological cross section and the results of a 3‐D gravity modeling that presumably “demands the presence of a high‐density mantle body placed within the crust in order to justify the observed anomalies.” Other authors have discussed before the possibility that the strong gravimetric (and magnetic) anomalies observed over the area could be explained, totally or partially, by bodies of mantle rocks located at shallow depths beneath the sediments of the Basque‐Cantabrian Basin (e.g., Pedreira et al, ; Roca et al, ; Tugend et al, ). However, the contribution by Pedrera et al () is novel in that it suggested that the present‐day crustal‐scale structure retains largely the morphology of the hyperextended Mesozoic basin and is only slightly modified by the Cenozoic Pyrenean orogeny. In their model, the continental crust is totally removed at present beneath the Cretaceous sediments of the northern part of the Basque‐Cantabrian Basin, so that these sediments are resting on top of the mantle, with the asthenosphere at only ~15‐km depth.…”

Section: Introductionmentioning

confidence: 99%

Comment on “Reconstruction of the Exhumed Mantle Across the North Iberian Margin by Crustal‐Scale 3‐D Gravity Inversion and Geological Cross Section” by Pedrera et al.

et al. 2018

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“…The Bay of Biscay and surrounding areas have been surveyed in order to understand its origin and evolution. Several attempts over the years have shed light on this issue, but still many unsolved questions and discrepancies remain (e.g., Boillot, ; Boillot, Malod, Dupeuble, & Cybere Group, ; Brunet, ; Choukroune & Mattauer, ; García‐Mondéjar, ; Gong, Langereis, & Mullender, ; Jammes, Manatschal, Lavier, & Masini, ; Malod & Mauffret, ; Olivet, , ; Pedrera et al, ; Rosenbaum, Lister, & Duboz, ; Roca, Muñoz, Ferrer, & Ellouz, ; Sibuet & Collette, ; Srivastava et al, ; Thinon, ; Tugend et al, ; Ubide et al, ). In this section, we integrate the new data obtained from the Gutiolo volcanism with published data on the evolution of the BCB and the Bay of Biscay.…”

Section: Bilbao Volcanism and The Opening Of Bay Of Biscaymentioning

confidence: 99%

“…Another low‐angle detachment fault extensional model for the Basque–Cantabrian Basin, in this case with the major fault dipping southward, has been proposed recently (Pedrera et al, ). In this model, accumulated extension from the Berriasian to the Aptian base is only 3%, and no major steep faults cutting the whole crust are considered.…”

Section: Bilbao Volcanism and The Opening Of Bay Of Biscaymentioning

confidence: 99%

The Early Aptian volcanic episode of Gutiolo (N Spain): Expression of the Bilbao Rift Fault Zone

et al. 2018

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The Gutiolo volcanic unit belongs to the Aptian Bilbao Formation and crops out 6 km SE of Bilbao (N Spain) within marine marlstones. It is 300 m thick and up to 1 km long. The volcanics consist of lava in the lower part and volcaniclastic sediments above, with metatrachytes and metatrachybasalts, similar to others of the alkali Cretaceous sequence in the Basque–Cantabrian Basin. The palaeontological age is top early Aptian (Dufrenoyia furcata Zone) near the Bedoulian–Gargasian substage transition, and the isotopic age (K–Ar) is 123 ± 3 Ma but most probably, 122 Ma. E–W and N–S trending faults bounding the Gutiolo volcanics controlled magma eruption. Other NW‐ and SE‐oriented major faults in the Bilbao area favoured several Valanginian to Santonian eruptions including Gutiolo. The eruptions moved progressively in space and time from SW to NE. These faults make up a 15‐km‐wide tectonic belt, the magma‐leaky Bilbao Fault Zone. A similar magmatic fault zone NE of Bilbao, Gernika‐Elgoibar, poured magma onto the sea floor during the late Albian–Cenomanian up to the Santonian, continuing the north‐easterly younging trend of volcanic inceptions recognized in Bilbao. All this Cretaceous volcanism is related to the Bay of Biscay opening processes, and the Gutiolo event is correlated with the first appearance of oceanic crust in the Bay of Biscay. From stratigraphic, volcanic, geochemical, and mineralization evidence, we attribute Gutiolo to an early phase of mafic intrusion emplacement in the Bilbao area, underplated by magmatism during the Valanginian to Santonian (Cretaceous). Volcanic hydrothermal fluids associated to the Gutiolo event are considered responsible for metallic ore emplacement in the Basque–Cantabrian Basin during the early Aptian.

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Reconstruction of the Exhumed Mantle Across the North Iberian Margin by Crustal‐Scale 3‐D Gravity Inversion and Geological Cross Section

Cited by 69 publications

References 78 publications

The Nappe des Marbres Unit of the Basque‐Cantabrian Basin: The Tectono‐thermal Evolution of a Fossil Hyperextended Rift Basin

The Nappe des Marbres Unit of the Basque‐Cantabrian Basin: The Tectono‐thermal Evolution of a Fossil Hyperextended Rift Basin

Comment on “Reconstruction of the Exhumed Mantle Across the North Iberian Margin by Crustal‐Scale 3‐D Gravity Inversion and Geological Cross Section” by Pedrera et al.

The Early Aptian volcanic episode of Gutiolo (N Spain): Expression of the Bilbao Rift Fault Zone

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