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The tectono-sedimentary evolution of a hyper-extended rift basin: the example of the Arzacq–Mauléon rift system (Western Pyrenees, SW France)

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Abstract

In this paper, we present a sedimentary and structural analysis that together with maps, sections and new Ar/Ar data enable to describe the tectono-sedimentary evolution of the Mauléon hyper-extended rift basin exposed in the W-Pyrenees. Hyper-extension processes that ultimately resulted in exhuming mantle rocks are the result of the subsequent development of two diachronous detachment systems related to two evolutional stages of rifting. An initial Late Aptian Early Albian crustal thinning phase is first recorded by the development of a crustal necking zone controlled by the north-vergent Southern Mauléon Detachment system. During a subsequent exhumation phase, active faulting migrates to the north with the emplacement of the Northern Mauléon detachment system that exhumed north section thinned continental crust and mantle rocks. This diachronous crustal thinning and exhumation processes are also recorded by the diachronous deposition of syn-tectonic sedimentary tracts above the two supra-detachment sub-basins. Syn-tectonic sedimentary tracts record the progressive exhumation of footwall rocks along detachment systems. Tectonic migration from the southern to the northern Mauléon Detachment system is recorded by the coeval deposition of “sag” deposits above the necking zone basin and of syn-tectonic tracts above exhumed rocks north section. Located on a hanging-wall situation related to the Mauléon hyper-extension structures, the Arzacq Basin also records a major crustal thinning phase as shown by its subsidence evolution so as by deep seismic images. The absence of major top-basement structures and its overall sag morphology suggest that crustal thinning processes occurred by decoupled extension of lower crustal levels contrasting with the Southern Mauléon Detachment system. Reconciling observations from the Mauléon and Arzacq Basins, we finally propose in this paper that they were the result of one and the same asymmetric crustal thinning and exhumation processes, where extension is accommodated into the upper crust in the Mauléon Basin (lower plate basin) and relayed in ductile lower crust below the Arzacq Basin (upper plate basin).

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References

  • Azambre B, Rossi M (1976) Le magmatisme alcalin d’âge crétacé dans les Pyrénées occidentales et l’arc basque; ses relations avec le métamorphisme et la tectonique. Bull Soc Géol France 7(18):1725–1728

    Google Scholar 

  • Barnolas A, Chiron JC (eds) (1996) Synthèse géologique et géophysique des Pyrénées: cycle hercynien. B.R.G.M, Orléans

    Google Scholar 

  • Beslier MO, Royer JY, Girardeau J, Hill PJ, Boeuf E, Buchanan C, Chatin F, Jacovetti G, Moreau A, Munschy M, Partouche C, Robert U, Thomas S (2004) A wide ocean-continent transition along the southwestern Australian margin; first results of the MARGAU/MD110 cruise. Bull Soc Géol France 175(6):641

    Google Scholar 

  • Biteau JJ, Canérot J (2007) La chaîne des Pyrénées et ses avants-pays d’Aquitaine et de l’Ebre: caractéristiques structurales, évolution géodynamique et tectono-sédimentaire. Géologues 155:16–28

    Google Scholar 

  • Biteau JJ, Le Marrex A, Le Vot M, Masset JM (2006) The Aquitaine Basin. Petrol Geos 12:247–273

    Google Scholar 

  • Boirie JM, Souquet P (1982) Les poudingues de Mendibelza: dépôs de cônes sous-marins du rift Albien des Pyrénées. Bull Cent Rech Explor Prod Elf Aquitaine 6(2):405–435

    Google Scholar 

  • Bois C, Gariel O, Lefort JP, Rolet J, Brunet MF, Masse P, Olivet JL (1997) Geologic contribution of the Bay of Biscay deep seismic survey: a summary of the main scientific results, a discussion of the open questions and suggestions for further investigations. Soc Géol Fr Mém 171:193–209

    Google Scholar 

  • Boissonnas J, Destombes JP, Heddebaut C, Le Pochat G, Lorsignol S, Roger P, Ternet Y (1974) Feuille d’Iholdy. Carte géologique de la France, scale 1/50000, Bur Rech Geol Min, Orléans, France

  • Brgm, Esso, Snpa (1974) Géologie du bassin d’Aquitaine. Orléans, France

    Google Scholar 

  • Brunet MF (1984) Subsidence history of the Aquitaine basin determined from subsidence curves. Geol Mag 121:421–428

    Google Scholar 

  • Brunet MF, Boillot G (1991) Subsidence et géodynamique du bassin d’Aquitaine. Relations avec l’ouverture de l’Atlantique. Thèse d’Etat, Université de Paris 6, Paris, France

  • Canérot J (1989) Rifting éocrétacé et halocinèse sur la marge ibérique des Pyrénées Occidentales (France). Conséquences structurales. Bull Cent Rech Explor Prod Elf Aquitaine 13:87–99

    Google Scholar 

  • Canérot J (2008) Les Pyrénées—Histoire Géologique. Atlantica, BRGM éditions, p 516

  • Canérot J, Villien A, Lenoble L (1990) Sequence stratigraphy and sedimentary unconformities: western Pyrenees (field data) and southern Aquitanian basin (subsurface data): examples. Bull Soc Géol France 8:995–1000

    Google Scholar 

  • Canérot J, Majeste-Menjoulas C, Ternet Y, James V, Fabre R, Desrumaux C, Lebourg T (2001) Les glissements rocheux du versant sud du Layens (Vallée d’Aspe, Pyrénées occidentales). Bull Soc Géol France 172:779–784

    Google Scholar 

  • Casteras M (1969) Geological map sheet of Mauléon-Licharre, 1/80000. BRGM Orléans, France

  • Casteras M, Souquet P (1966) Sur les accidents de la couverture de la zone primaire axiale au Sud du massif de Mendibelza (Basses-Pyrenees). C R Soc Géol France 9:369

    Google Scholar 

  • Casteras M, Canérot J, Paris JP, Tisin D, Azambre B, Alimen H (1970a) Feuille d’Oloron Sainte Marie. Carte géologique de France au 1/50 000, Orléans, France

  • Casteras M, Souquet P, Culot G, Galharague J, Frey M, Ribis R, Paris JP (1970b) Feuille de Larrau. Carte géologique de France au 1/50 000, Orléans, France

  • Casteras M, Gottis M, Clin M, Guignard JD, Paris JP, Galharague J, Frey M (1971) Feuille de Tardets Sorholus. Carte Géologique de France au 1/50 000, Orléans, France

  • Claude D (1990) Etude stratigraphique, sédimentologique et structurale des dépôts mésozoïques au Nord du massif du Labourd. Rôle de la faille de Pamplona (Pays Basque). PhD thesis, Université de Bordeaux III, pp 252

  • Clerc C, Lagabrielle Y, Neumaier M, Reynaud J-Y, de Saint Blanquat M (2012) Exhumation of subcontinental mantle rocks: evidence from ultramafic-bearing clastic deposits nearby the Lherz peridotite body, French Pyrenees. Bull Soc Geol Fr 183(5):443–459

    Google Scholar 

  • Curnelle R (1983) Evolution structuro-sédimentaire du Trias et de l’infra-Lias d’Aquitaine. Bull Cent Rech Explor Prod Elf Aquitaine 7:69–99

    Google Scholar 

  • Daignières M, Seguret M, Specht M, Team E (1994) The Arzacq-Western Pyrenees ECORS deep seismic profile. Publ Eur Assoc Pet Geol Mem 4:199–208

    Google Scholar 

  • Debroas EJ, Canérot J, Billote M (2010) Les brèches d’Urdach, témoins de l’exhumation du manteau pyrénéen dans un escarpement de faille vraconien-cénomanien inférieur (Zone Nord Pyrénéenne, Pyrénées Atlantiques, France). Géol France 2:53–65

    Google Scholar 

  • Ducasse L, Vélasque P (1986a) Glissement de couverture et panneaux basculés dans la région des Arbailles (Pyrénées occidentales): un modèle évolution crétacé de la marge nord-ibérique à l’Est de la transformante de Pamplona. C R Acad Sci 303(16):1477–1482

    Google Scholar 

  • Ducasse L, Vélasque PC (1986b) Tectonique et sédimentation dans la couverture des Pyrénées occidentale (Haute Soule). Arguments en faveur de la plaque ibérique sous la plaque européenne. C R Acad Sci 302(16) :1027–1032

  • Ducasse L, Velasque PC (1988) Géotraverse dans la partie occidentale des pyrénées de l’avant-pays aquitain au bassin de l’Ebre. Effet d’une inversion structurale sur l’édification d’une chaîne intracontinentale. PhD thesis, Université d’Aix-Marseille, Aix-en-Provence, France

  • Esquevin J, Fournie P, de Lestang J (1971) Les séries de l’Aptien et de l’Albien des régions nord-pyrénéennes et sud-aquitaines (France Sud). Bull Cent Rech Explor Prod Elf Aquitaine 5:87–151

    Google Scholar 

  • Flamand JM, Curnelle R (1982) Reconnaissance de l’allochtonie du massif cristallin du Labourd (Pyrénées Atlantiques). In: BRGM (ed) Programme Géologie Profonde de la France: Colloque National, Paris, pp 289–293

  • Fréchengues M (1993) Stratigraphie séquentielle et micropaléontologie du Trias moyen-supérieur des Pyrénées franco-espagnoles. PhD thesis, Université de Toulouse 3, Toulouse, France

  • Gallart J, Banda E, Daignières M (1981) Crustal structure of the Paleozoic-Axial-Zone of the Pyrenees and the transition to the North Pyrenean Zone. Ann Geophys 37(3):457–480

    Google Scholar 

  • Gottis M (1972) Construction d’un modèle géodynamique pyrénéen. C R Acad Sci 275:2102

    Google Scholar 

  • Grandjean G (1992) Etudes des structures crustales dans une portion de la chaîne et de leur relation avec les bassins sédimentaires. Application auc Pyrénées Occidentales au travers du projet ECORS-Arzacq-Pyrénées. PhD thesis, Université de Montpellier III, Montpellier, France

  • Heddebaut C (1973) Etudes géologiques dans les massifs Paléozoïques Basques. PhD thesis, Université des Sciences et Techniques de Lille, Lille, France

  • Huismans R, Beaumont C (2003) Symmetric and asymmetric lithospheric extension: relative effects of frictional-plastic and viscous strain softening. J Geophys Res 108:2496

    Google Scholar 

  • Huismans RS, Beaumont C (2008) Complex rifted continental margins explained by dynamical models of depth-dependent lithospheric extension. Geology 36(2):163–166

    Google Scholar 

  • James V, Canérot J (1999) Diapirisme et structuration post-triasique des Pyrénées occidentales et de l’Aquitaine méridionales (France). Eclogae Geol Helv 92:63–72

    Google Scholar 

  • James V, Canérot J, Biteau JJ (1996) Données nouvelles sur la phase de rifting atlantique des Pyrénées occidentales au Kimméridgien. Géol Fr 3:66

    Google Scholar 

  • Jammes S, Manatschal G, Lavier L, Masini E (2009) Tectono-sedimentary evolution related to extreme crustal thinning ahead of a propagating ocean; example of the western Pyrenees. Tectonics 28 (TC4012)

  • Jammes S, Lavier LL, Manatschal G (2010a) Extreme crustal thinning in the Bay of Biscay and the Western Pyrenees: from observations to modeling. G3 11

  • Jammes S, Manatschal G, Lavier LL (2010b) Interaction between prerift salt and detachment faulting in hyperextended rift systems: the example of the Parentis and Mauléon basins (Bay of Biscay and western Pyrenees). AAPG Bull 94(7):957–975

    Google Scholar 

  • Jammes S, Tiberi C, Manatschal G (2010c) 3D architecture of a complex transcurrent rift system: the example of the Bay of Biscay–Western Pyrenees. Tectonophysics 489(1):210–226

    Google Scholar 

  • Johnson JA, Hall CA (1989a) The structural and sedimentary evolution of the Cretaceous North Pyrenean Basin, southern France. Geol Soc Am Bull 101:231–247

    Google Scholar 

  • Johnson JA, Hall CA (1989b) Tectono-stratigraphic model for the massif d’Igountze-Mendibelza, western Pyrenees. J Geol Soc Lond 146:925–932

    Google Scholar 

  • Karson JA, Frueh-Green GL, Kelley DS, Williams EA, Yoerger DR, Jakuba M (2006) Detachment shear zone of the Atlantis Massif core complex, Mid-Atlantic Ridge, 30 degrees N. G3 7 (6)

  • Lagabrielle Y, Bodinier JL (2008) Submarine reworking of exhumed subcontinental mantle rocks; field evidence from the Lherz peridotites, French Pyrenees. Terra Nova 20(1):11–21

    Google Scholar 

  • Lagabrielle Y, Labaume P, De Saint Blanquat M (2010) Mantle exhumation, crustal denudation, and gravity tectonics during Cretaceous rifting in the Pyrenean realm (SW Europe): insights from the geological setting of the lherzolite bodies. Tectonics 29 (TC4012)

  • Larrasoaña JC, Parès JM, Millàn H, del Valle J, Pueyo EL (2003) Paleomagnetic, structural and stratigraphic constraints on transverse fault kinematics during basin inversion: the Pampelona fault (Pyrenees, north Spain). Tectonics 22 (TC1071)

  • Lavier L, Manatschal G (2006) Mechanism to thin continental lithosphere at magma poor margins. Nature 440:324–328

    Google Scholar 

  • Le Pochat G, Bolthenhagen C, Lenguin M, Lorsignol S, Thibault C (1976) Feuille de Mauléon-Licharre. Carte géologique de France au 1/50 000, Orléans, France

  • Le Pochat G, Heddebaut C, Lenguin M, Lorsignol S, Souquet P, Muller J, Roger P (1978) Feuille de St Jean Pied de Port. Carte Géologique de France au 1/50 000, Orléans, France

  • Leau H. (1997) Etude du signal sismique et de son atténuation dans la croûte inférieure réflective. Application au profil ECORS-Golfe de Gascogne. PhD thesis, Université de Brest, Brest, France

  • Manatschal G (1999) Fluid- and reaction-assisted low-angle normal faulting; evidence from rift-related brittle fault rocks in the Alps (Err Nappe, eastern Switzerland). J Struct Geol 21:777–793

    Google Scholar 

  • Manatschal G (2004) New models for evolution of magma-poor rifted margins based on a review of data and concepts from West Iberia and the Alps. Int J Earth Sci 93(3):432–466

    Google Scholar 

  • Manatschal G, Nievergelt P (1997) A continent-Ocean transition recorded in the Err and Platta nappes (Eastern Switzerland). Eclogae Geol Helv 90:3–27

    Google Scholar 

  • Masini E, Mohn G, Manatschal G, Ghienne JF, Lafont F (2011) The tectono-sedimentary evolution of deep-water magma-poor rifted-margins: the example of the Zone of Samedan preserved in the Err nappe in SE-Switzerland. Basin Res 23(6):652–677

    Google Scholar 

  • Masini E, Manatschal G, Mohn G, Unternehr P (2012) Anatomy and tectono-sedimentary evolution of a rift-related detachment system: the example of the Err Detachment (Central Alps, SE Switzerland). Geol Soc Am Bull 124:1535–1551

    Google Scholar 

  • Masini E, Manatschal G, Mohn G (2013) The Alpine Tethys rifted margins: reconciling old and new ideas to understand the stratigraphic architecture of magma-poor rifted margins. Sedimentology 60:174–196

    Google Scholar 

  • Miller MB, Pavlis TL (2005) The Black Mountains turtlebacks; Rosetta stones of Death Valley tectonics. Earth-Sci Rev 73:115–138

    Google Scholar 

  • Miranda-Avilès R, Bourrouilh R, Nava-Sanchez EH, Puy-Alquiza MJ, Bourrouilh-Le Jan F (2005) Analyse comparée de bassins sédimentaires transtensionnels: le bassin de Santa Rosalia (Basse Californie du Sud, Mexique) et de Mendibelza (Pyrénées, France). Estudios Geol 61:161–176

    Google Scholar 

  • Montigny R, Azambre B, Rossy M, Thuizat R (1986) K-Ar study of Cretaceous magmatism and metamorphism from Pyrenees; age and length of rotation of the iberian peninsula. Tectonophysics 129:257–274

    Google Scholar 

  • Mulder T, Zaragosi S, Razin P, Grelaud C, Lanfumey V, Bavoil F (2009) A new conceptual model for the deposition process of homogenite: application to a cretaceous megaturbidite of the western Pyrenees (Basque region, SW France). Sed Geol 222:263–273

    Google Scholar 

  • Muñoz JA (1992) Evolution of a continental collision belt: ECORS-Pyrenees crustal balanced section. In: McClay KR (ed) Thrust tectonics. Chapman and Hall, London, pp 235–246

    Google Scholar 

  • Osmundsen PT, Ebbing J (2008) Styles of extension offshore mid-Norway and implications for mechanisms of crustal thinning at passive margins. Tectonics 27 (TC6016)

  • Péron-Pinvidic G, Manatschal G (2009) The final rifting evolution at deep magma-poor passive margins from Iberia-Newfoundland; a new point of view. Intern J Earth Sci 98(7):1581–1597

    Google Scholar 

  • Péron-Pinvidic G, Manatschal G, Minshull TA, Sawyer, DS (2007) Tectonosedimentary evolution of the deep Iberia Newfoundland margins: evidence for a complex breakup history. Tectonics 26(2). doi:10.1029/2006TC001970

  • Péron-Pinvidic G, Manatschal G, Osmundsen PT (2013) Structural comparison of archetypal Atlantic rifted margins: a review of observations and concepts. Mar Pet Geol 43:21–47

    Google Scholar 

  • Pinet B, Montadert L, Curnelle R, Cazes M, Marillier F, Rolet J, Tomassino A, Galdeano A, Patriat P, Brunet MF, Olivet JL, Schaming M, Lefort JP, Arrieta A, Riaza C (1987) Crustal thinning on the Aquitaine shelf, Bay of Biscay, from deep seismic data. Nature 325:513–516

    Google Scholar 

  • Puigdefàbregas C, Souquet P (1986) Tecto-sedimentary cycles and depositional sequences of the Mesozoic and Tertiary from the Pyrenees. Tectonophysics 129:173–203

    Google Scholar 

  • Razin P (1989) Evolution tecto-sédimentaire alpine des Pyrénées basques à l’Ouest de la transformante de Pampelona. PhD thesis, Université de Bordeaux, Bordeaux, France

  • Roca E, Muñoz JA, Ferrer O, Ellouz N (2011) The role of the Bay of Biscay Mesozoic extensional structure in the configuration of the Pyrenean orogen: constraints from the MARCONI deep seismic reflection survey. Tectonics 30 (TC2001)

  • Rossi P, Cocherie A, Mark Fanning C, Ternet Y (2003) Datation U-Pb sur zircons des dolarites tholéïtiques pyrénéennes (ophites) à la limite Trias-Jurassique et relation avec les tufs volcaniques dits “infra-liasiques” nord-pyrénéens. C R Géosci 335:1071–1080

    Google Scholar 

  • Schoeffler J (1982) Les transversales basco-landaises. Bull Cent Rech Explor Prod Elf Aquitaine 6:257–263

    Google Scholar 

  • Serrano O, Delmas J, Hanot F, Vially J, Herbin JP, Houel P, Tourtiere B (2006) Le bassin d’Aquitaine: valorisation des données sismiques, cartographie structurale et potentiel pétrolier. BRGM, Orléans

    Google Scholar 

  • Souquet P, Deramond J (1989) Séquence de chevauchements et séquences de dépot dans un bassin d’avant-fosse. Exemple du sillon crétacé du versant sud des Pyrénées (Espagne). C R Acad Sci 309:137–144

    Google Scholar 

  • Souquet P, Debroas EJ, Boirie JM, Pons P, Fixari G, Roux JC, Dol J, Thieuloy JP, Bonnemaison M, Manivit H, Peybernès B (1985) The black flysh group (Albian-Cenomanian) of the Pyrenees. Bull Cent Rech Explor Prod Elf-Aquitaine 9:183–252

    Google Scholar 

  • Sutra E, Manatschal G, Mohn G, Unternehr P (2013) Quantification and restoration of extensional deformation along the Western Iberia and Newfoundland rifted margins. Geochem Geophys Geosyst 14(8):2575–2597

    Google Scholar 

  • Teixell A (1990) Alpine thrusts at the western termination of the Pyrenean Axial Zone. Bull Soc Géol France 8(6):241–249

    Google Scholar 

  • Teixell A (1998) Crustal structure and orogenic material budget in the western central Pyrenees. Tectonics 17:395–406

    Google Scholar 

  • Thinon I (1999) Structure profonde de la Marge Nord Gascogne et du Bassin Armoricain. PhD thesis, Ifremer-IUEM, Brest, France

  • Twiss RJ, Moores EM (2007) Structural geology, 2nd edn. W.H. Freeman, New York

    Google Scholar 

  • Unternehr P, Péron-Pinvidic G, Manatschal G, Sutra E (2010) Hyper-extended crust in the South Atlantic: in search of a model. Petrol Geosci 16(3):207–215

    Google Scholar 

  • Velasque PC, Ducasse L, Muller J, Scholten R (1989) The influence of inherited extensional structures on the tectonic evolution of an intracratonic chain: the example of the Western Pyrenees. Tectonophysics 162(3–4):243–264

    Google Scholar 

  • Vielzeuf P (1984) Relations de phases dans le facies granulite et implications géodynamiques: l’exemple des granulites des Pyrénées. Thesis, Université Blaise Pascal Clermont-Ferrand II, Clermont-Ferrand, France

  • Vissers RLM, Meijer PT (2011) Mesozoic rotation of Iberia: subduction in the Pyrenees? Earth-Sci Rev 110(1):93–110

    Google Scholar 

  • Wilson RCL, Manatschal G, Wise S (2001) Rifting along non-volcanic passive margins; stratigraphic and seismic evidence from the Mesozoic successions of the Alps and western Iberia. In: Wilson RCL, Whitmarsh RB, Taylor B, Froitzheim N (eds) Non-volcanic rifting of continental margins; a comparison of evidence from Land and Sea: Geol Soc (London) Spec Pub 187, pp 429–452

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  1. IPGS/CNRS 7516, 1 rue Blessig, 67084, Strasbourg Cedex, France

    Emmanuel Masini, Gianreto Manatschal, Julie Tugend & Geoffroy Mohn

  2. TOTAL-Exploration Production/Projets Nouveaux Place Jean Millier, La Défense 6, 92078, Paris la Defense Cedex, France

    Jean-Marie Flament

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Masini, E., Manatschal, G., Tugend, J. et al. The tectono-sedimentary evolution of a hyper-extended rift basin: the example of the Arzacq–Mauléon rift system (Western Pyrenees, SW France). Int J Earth Sci (Geol Rundsch) 103, 1569–1596 (2014). https://doi.org/10.1007/s00531-014-1023-8

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