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Home All issues Volume 196 (2025) BSGF - Earth Sci. Bull., 196 (2025) 23 References
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Issue
BSGF - Earth Sci. Bull.
Volume 196, 2025
Article Number 23
Number of page(s) 19
DOI https://doi.org/10.1051/bsgf/2025012
Published online 03 December 2025
  • Aerden DGAM. 1998. Tectonic evolution of the Montagne Noire and a possible orogenic model for syncollisional exhumation of deep rocks, Variscan belt, France. Tectonics 17: 62–79. [Google Scholar]
  • Aerden DGAM, Malavieille J. 1999. Origin of a large-scale fold nappe in the Montagne Noire, Variscan belt, France. J Struct Geol 21: 1321–1333. [Google Scholar]
  • Alabouvette B, Demange M, Guérangé-Lozes J, Ambert P. 2003. Notice et carte géologique de la France (1/250000) feuille de Montpellier. Orléans: BRGM, p 164. [Google Scholar]
  • Arthaud F. 1970. Etude tectonique et microtectonique comparée de deux domaines hercyniens: les nappes de la Montagne Noire (France) et l’anticlinorium de l’Iglesiente (Sardaigne). Thèse 3ème cycle, Université des Sciences et Techniques du Languedoc, pp. 175. [Google Scholar]
  • Ballèvre M, Manzotti P, Dal Piaz GV. 2018. Pre-Alpine (Variscan) inheritance: a key for the location ofthe future Valaisan Basin (Western Alps). Tectonics 37: 786–817. https://doi.org/10.1002/2017TC004633. [CrossRef] [Google Scholar]
  • Bard JP, Ramboloson R. 1973. Métamorphisme plurifacial et sens de variation du degrès géothermique durant la tectogenèse polyphasée hercynienne dans la partie orientale de la zone axiale de la Montagne Noire (massif du Caroux, sud du Massif Central français). Bull Soc Geol Fr 15: 579–586. [Google Scholar]
  • Beaud F. 1985. Etude structurale de la Zone Axiale orientale de la Montagne Noire (Sud du Massif Central Français). Détermination des mécanismes de déformation. Relation avec les nappes du Versant Sud: Thèse 3ème cycle. Université des Sciences et Techniques du Languedoc, Montpellier 191 pp. [Google Scholar]
  • Bouchardon JL, Dechomets R, Demange M. 1979. A propos du disthène en roche dans les micaschistes et gneiss du synclinal de Rosis et du flanc Sud, zone axiale de la Montagne Noire. CR Acad Sci Paris 288: 1067–1069. [Google Scholar]
  • Brun JP, Van Den Driessche J. 1994. Extensional gneiss domes and detachment fault systems: structure and kinematics. Bull Soc Geol Fr 165 (6): 519–530. [Google Scholar]
  • Brun JP, Van Den Driessche J. 1996. Réponse à observations et remarques sur l’article “Extensional gneiss domes and detachment fault systems/structure and kinematics (Brun, J.P., Van Den Driessche, J., 1994, Bull. Soc. Géol. Fr. 165 (6), 519–530)”. Bull Soc Geol Fr 167 (2): 295–302. [Google Scholar]
  • Brunel M, Lansigu C. 1997. Deformation and kinematics of emplacement of the axial dome of the Montagne Noire: implications of quartz-sillimanite nodule attitudes (French Massif Central). C R Acad Sci Paris II 325 (7): 517–523. [Google Scholar]
  • Chardon D, Aretz M, Roques D. 2020. Reappraisal of Variscan tectonics in the southern French Massif Central. Tectonophysics 787: 228477. https://doi.org/10.1016/j.tecto.2020.228477. [CrossRef] [Google Scholar]
  • Cocherie A, Baudin T, Autran A, Guerrot C, Fanning M, Laumonier B. 2005. UPb zircon (ID-TIMS and SHRIMP) evidence for the early Ordovician intrusion of meta-granites in the late Proterozoic Canaveilles Group of the Pyrenees and the Montagne Noire (France). Bull. Soc. Geol. Fr 176, 269282. [Google Scholar]
  • Cohen M. 1975. La lherzolite à grenat et spinelle de l’étang de l’Airette. CR Acad Sci Paris Sér D 280: 537–540. [Google Scholar]
  • Demange M. 1975. Style pennique de la Zone Axiale de la Montagne Noire entre Saint-Pons et Murat-sur-Vèbre (Massif Central). Bulletin du Bureau de Recherches Géologiques et Minières, 2, 2: 269–291. [Google Scholar]
  • Demange M. 1982. Etude géologique du Massif de l'Agoût, Montagne Noire, France. A geologic study of the Agoût Massif, Montagne Noire, France. Doctoral. Univ, Paris VI. [Google Scholar]
  • Demange M. 1985. The eclogite-facies rocks of the Montagne Noire, France. Chem Geol 50: 173–188. [Google Scholar]
  • Demange M. 1999. Evolution tectonique de la Montagne Noire : un modèle en transpression. CR Acad Sci Paris 329: 823–829. [Google Scholar]
  • Demange M, Guérangé-Lozes J, Guérangé B. 1996. Carte géologique de Lacaune et sa notice. In : Carte géologique de la France au 1:50000 n° 987. Bureau de Recherches Géologiques et Minières, Orléans, France. [Google Scholar]
  • Den Tex E. 1975. Thermally mantled gneiss domes; the case for convective heat ow in more or less solid orogenic basement. In: Borradaile, G.J., Ritsema, A.R., Rondeel, H.E., Simon, O.J. (Eds.), Geodynamics Project, Scientific Report. North-Holland Publ. Co, Amsterdam, Netherlands. [Google Scholar]
  • Didier A, Bosse V, Boulvais, et al., 2013. Disturbance versus preservation of U-Th-Pb ages in monazite during fluid-rock interaction: textural, chemical and isotopic in situ study in microgranites (Velay Dome, France). Contrib Miner Petrol 165: 1051–1072. [Google Scholar]
  • Doublier MP, Potel S, Wemmer K. 2014. The tectono-metamorphic evolution of the very low-grade hanging wall constrains two stage gneiss dome formation in the Montagne Noire example (S-France). J Metamorph Geol. https://doi.org/10.1111/jmg.12111. [Google Scholar]
  • Echtler H, Malavieille J. 1990. Extensional tectonics, basement uplift and Stephano-Permian collapse basin in a late Variscan metamorphic core complex (Montagne Noire, southern Massif Central). Tectonophysics 177: 125–138. [Google Scholar]
  • Engel W, Feist R, Franke W. 1980. Le Carbonifère anté-stéphanien de la Montagne Noire : rapports entre mise en place des nappes et sédimentations. Bull BRGM 2: 341–389. [Google Scholar]
  • Faure M, Cottereau N. 1988. Données cinématiques sur la mise en place du dôme migmatitique carbonifère moyen de la zone axiale de la Montagne Noire (Massif Central, France). CR Acad Sci Paris 307: 1787–1794. [Google Scholar]
  • Faure M, Lardeaux JM, Ledru P. 2009. A review of the pre-Permian geology of the French Massif Central. Comptes Rendus Géosciences 341, 202213, https://doi.org/10.1016/j.crte.2008.12.001 [Google Scholar]
  • Faure M, Cocherie A, Bé Mézène E, Charles N, Rossi P. 2010. Middle Carboniferous crustal melting in the Variscan belt: new insights from U-Th-Pbtot monazite and U-Pb zircon ages of the Montagne Noire Axial Zone (southern French Massif Central). Gondwana Res 18: 653–673. [Google Scholar]
  • Faure M, Cocherie A, Gaché J, et al. 2014. Middle Carboniferous intracontinental subduction in the outer zone of the Variscan belt (Montagne Noire Axial Zone, French Massif Central): multimethod geochronological approach of polyphase metamorphism. Geol Soc Lond Spec Pub 405 (1): 289–311. [Google Scholar]
  • Feist R, Galtier J. 1985. Découverte de flores d’âge namurien probable dans le flysch à olistolithes de Cabrières (Hérault). Implications sur la durée de la sédimentation synorogénique dans la Montagne Noire (France Méridionale). CR Acad Sci Paris 300: 207–212. [Google Scholar]
  • Feng R, Machado N, Ludden J. 1993. Lead geochronology of zircon by laser-probe-inductively coupled plasma mass spectrometry (LP-ICPMS). Geochim Cosmochim Acta 57: 3479–3486. [Google Scholar]
  • Franke W, Doublier MP, Klama K, Potel S, Wemmer K. 2011. Hot metamorphic core complex in a cold foreland. Int J Earth Sci 100: 753–785 [Google Scholar]
  • Fréville K, Cenki-Tok B, Trap P, et al. 2016. Thermal interaction of middle and upper crust during gneiss dome formation: example from the Montagne Noire (French Massif Central). J Metamorph Geol 34: 447–462. https://doi.org/10.1111/jmg.12188. [Google Scholar]
  • Fryer BJ, Jackson SE, Longerich HP. 1993. The application of laser ablation microprobe-inductively coupled plasma-mass spectrometry (LAM-ICP-MS) to in situ (U)-Pb geochronology. Chem Geol 109: 1–8. [Google Scholar]
  • Gardés E, Montel JM, Seydoux-Guillaum AM, Wirth R. 2007. Pb diffusion in monazite: New constraints from the experimental study of Pb2+ ↔ Ca2+ interdiffusion. Geochim Cosmochim Acta 71 : 4036–4043. [Google Scholar]
  • Géze B. 1949. Etude géologique de la Montagne Noire et des Cévennes méridionales. Soc Géol Fr Mém 62: 1–125. [Google Scholar]
  • Hamelin C, Withney DL, Roger F, Teyssier C. 2022. Orogenic eclogites record relative magnitude of deep crustal flow and extent of migmatite-eclogite interaction. Lithos 434-435: 106917. https://doi.org/10.1016/j.lithos.2022.106917. [Google Scholar]
  • Harlov DE, Anczkiewicz R, Dunkley DJ. 2023. Metasomatic alteration of zircon at lower crustal P-T conditions utilizing alkali- and F-bearing fluids: Trace element incorporation, depletion, and resetting the zircon geochronometer. Geochim Cosmochim Acta 352: 222–235. [Google Scholar]
  • Hawkins D, Bowring S. 1997. U-Pb systematics of monazite and xenotime: case studies from the Paleoproterozoïc of the Grand Canyon, Arizona. Contrib Miner Petr 127: 87–103. [Google Scholar]
  • Hurai V, Paquette JL, Huraiovà M, Konecny P. 2010. U-Th-Pb geochronology of zircon and monazite from syenite and pincinite xenoliths in Pliocene alkali basalts of the intra-carpathian back-arc basin. J Volcanol Geotherm Res 198: 275–287. [Google Scholar]
  • Jaffey AH, Flynn KF, Glendenin LE, Bentley WC, Essling AM. 1971. Precision measurement of half-lives and specific activities of 235U and 238U. Phys Rev C4: 1889–1906. [Google Scholar]
  • Ludwig KR. 2001. User Manual for Isoplot/Ex Rev. 2.49. A Geochronological Toolkit for Microsoft Excel. Berkeley Geochronology Center Special Publication 1a pp. 1–56. [Google Scholar]
  • Magontier J. 2023. Les orthogneiss de la Zone Axiale de la Montagne Noire (Sud du Massif Central, France). Analyse et synthèse des données bibliographiques. Conséquences lithostratigraphiques et structurales. Carnets Natures 10: 11–38. [Google Scholar]
  • Malavieille J. 2010. Impact of erosion, sedimentation and structural heritage on the structure and kinematics of orogenic wedges: analog models and case studies. GSA Today 20: 4–10. [Google Scholar]
  • Maluski H, Costa, S, Echtler H. 1991. Late Variscan tectonic evolution by thinning of earlier thickened crust: an 40Ar-39Ar study of the Montagne Noire, southern Massif Central, France. Lithos 26 (3-4): 287–304. [Google Scholar]
  • Mattauer M, Laurent PH, Matte PH. 1996. Plissement hercynien syn-schisteux post-nappe et étirement subhorizontal dans le versant sud de la Montagne Noire (Sud du Massif Central, France). Post-nappe syn-schistose Hercynian folding and horizontal stretching in the southern side of Montagne Noire, southern Central Massif, France. CR Acad Sci II 322 (4): 309–315. [Google Scholar]
  • Matte PH. 2007. Variscan thrust nappes detachments and strike-slip faults in the French Massif Central: interpretation of the lineations. Geol Soc Am Mem 200: 319–402. [Google Scholar]
  • Matte Ph, Lancelot J, Mattauer M. 1998. La Zone axiale hercynienne de la Montagne Noire n’est pas un “metamorphic core complex” extensif mais un anticlinal post-nappe à coeur anatectique. Geodin Acta (Paris) 11 (1): 13–22. [Google Scholar]
  • Michel LA, Tabor NJ, Montañez IP, Schmitz MD, Davydov VI. 2015. Chronostratigraphy and Paleoclimatology of the Lodève Basin, France: Evidence for a pan-tropical aridification event across the Carboniferous-Permian boundary. Palaeogeogr Palaeoclimatol Palaeoecol 430 (2015) 118–131 [Google Scholar]
  • Nicolas A, Bouchez JL, Blaise JL, Poirier JP. 1977. Geological aspects of deformation in continental shear zones. Tectonophysics 42: 55–73. [Google Scholar]
  • Ourzik A, Debat P, Mercier A. 1991 Metamorphic evolution of the N and Ne parts of the Montagne Noire Axial Zone (southern Massif-Central, France). CR Acad Sci Ser II 313 (13): 1547–1553 [Google Scholar]
  • Paquette JL, Piro JL, Devidal JL, Bosse V, Didier A. 2014. Sensitivity enhancement in LA-ICP-MS by N2 addition to carrier gas: application to radiometric dating of U-Th-bearing minerals. Agilent ICP-MS J 58: 4–5. [Google Scholar]
  • Pfeifer LS, Soreghan GS, Pochat S, Van Den Driessche J, Thomson SN. 2016. Rapid Permian exhumation of the Montagne Noire metamorphic core complex recorded in provenance of upper Paleozoic clastic strata in the Graissessac-Lodève Basin, France. Basin Res. https://doi.org/10.1111/bre.12197. [Google Scholar]
  • Pidgeon RT. 1992. Recrystallisation of oscillatory zoned zircon: some geochronological and petrological implications. Contrib Mineral Petrol 110: 463–472. [Google Scholar]
  • Pitra P, Poujol M, Van Den Driessche J, Poilvet JC, Paquette JL. 2012. Early Permian extensional shearing of an Ordovician granite: the Saint-Eutrope “C/S-like” orthogneiss (Montagne Noire, French Massif Central). CR Geosci. https://doi.org/10.1016/j.crte.2012.06.002. [Google Scholar]
  • Pitra P, Poujol M, Van Den Driessche J, et al. 2022. Late Variscan (315 Ma) subduction or deceptive zircon REE patterns and U-Pb dates from migmatite-hosted eclogites? (Montagne Noire, France). J Metamorph Geol 40: 39–65. https://doi.org/10.1111/jmg.12609. [CrossRef] [Google Scholar]
  • Poilvet JC, Poujol M, Pitra P, Van Den Driesssche J, Paquette JL. 2011. The Montalet granite, Montagne Noire, France: an Early Permian syn-extensional pluton as evidenced by new U-Th-Pb data on zircon and monazite. CR Geosci 343: 454–461. https://doi.org/10.1016/j.crte.2011.06.002. [Google Scholar]
  • Poujol M, Pitra P, Van Den Driessche F J, et al. 2017. Two-stage partial melting during the Variscan extensional tectonics (Montagne Noire, France). Int J Earth Sci. https://doi.org/10.1007/s00531-016-1369-1. [Google Scholar]
  • Poujol M, Mercuzot M, Lopez M, et al. 2023. Insights on the Permian tuff beds from the Saint-Affrique Basin (Massif Central, France): an integrated geochemical and geochronological study. CR Géosci Sci Planète 355. https://doi.org/10.5802/crgeos.184. [Google Scholar]
  • Rabin M, Trap P, Carry N, et al. 2015. Strain partitioning along the anatectic front in the Variscan Montagne Noire massif (southern French Massif Central). Tectonics. https://doi.org/10.1002/2014TC003790. [Google Scholar]
  • Raynal O. 2004. Etude des boudins amphibolitiques, péridotiques et éclogitiques dans leur position structurale le long de la coupe des Gorges d’Héric. Unpublished report. Université Montpellier 2, pp. 33. [Google Scholar]
  • Rey PF, Teyssier C, Kruckenberg SC, Whitney DL. 2011. Viscous collision in channel explains double domes in metamorphic core complexes. Geology 39 (4): 387–390. [Google Scholar]
  • Rey PF, Teyssier C, Kruckenberg SC, Whitney DL. 2012. Viscous collision in channel explains double domes in metamorphic core complexes. Geology 40 (10): e280. Forum Reply, October, 2012. https://doi.org/1130/G33202Y.1. [Google Scholar]
  • Rey PF, Mondy L, Duclaux G, et al. 2017. The origin of contractional structures in extensional gneiss domes. Geology 45 (3): 263–266. https://doi.org/10.1130/G38595.1. [Google Scholar]
  • Roger F, Respaut JP, Brunel M, Matte PH, Paquette JL. 2004. Première datation U-Pb des orthogneiss oeillés de la zone axiale de la Montagne Noire (Sud du Massif Central): nouveaux témoins du magmatisme ordovicien dans la chaîne varisque. CR Geosci Acad Sci Paris 336: 19–28. [Google Scholar]
  • Roger F, Teyssier C, Respaut JP, et al. 2015. Timing of deformation and exhumation of the Montagne Noire double dome, French Massif Central. Tectonophysics 640-641: 53–69. [Google Scholar]
  • Roger F, Teyssier C, Whitney DL, et al. 2020. Age of metamorphism and deformation in the Montagne Noire dome (French Massif Central): Tapping into the memory of fine-grained gneisses using monazite U-Th-Pb geochronology. Tectonophysics 776: 228–3136. [Google Scholar]
  • Schandl ES, Gorton MP. 2004. A textural and geochemical guide to the identification of hydrothermal monazite: criteria for selection of samples for dating epigenetic hydrothermal ore deposits. Econ Geol 99: 1027–1035. [Google Scholar]
  • Schaltegger U, Brack P. 2007. Crustal-scale magmatic systems during intracontinental strike-slip tectonics: U, Pb and Hf isotopic constraints from Permian magmatic rocks of the Southern Alps. Int J Earth Sci 96: 1131–1151. [Google Scholar]
  • Schuiling RD. 1960. Le dome gneissique de l’AgoÛt (Tarn et Hérault). Mémoires de la Sociéte Géologique de France. Nouv Ser 39 (91): 59. [Google Scholar]
  • Schuiling RD, Widt J. 1962. Sur la génèse du dôme gneissique de l'Agoût (Dépts Tarn et Hérault). Geol. Mijnb. Ned. 41, 321326. [Google Scholar]
  • Schuiling RD. 1963. Some remarks concerning the scarcity of retrograde vs. progressive metamorphism, Geologie en Mijnbouw. Neth. J. Geosci. 42 (5), 177179. [Google Scholar]
  • Seydoux-Guillaume AM, Paquette JL, Wiedenbeck M, Montel JM, Heinrich W. 2002. Experimental resetting of the UThPb systems in monazite. Chem. Geol. 191, 165181. [Google Scholar]
  • Soula JC, Debat P, Brusset S, et al. 2001. Thrust related, diapiric, and extensional doming in a frontal orogenic wedge: example of the Montagne Noire, southern French Hercynian Belt. J Struct Geol 23 (11): 1677–1699. [CrossRef] [Google Scholar]
  • Steiger RH, Jäger E. 1977. Subcommission on geochronology: convention on the use of decay constants in geo- and cosmochronology. Earth Planet Lett 36: 359–362. [Google Scholar]
  • Tartèse R, Boulvais P, Poujol M, et al. 2012. Mylonites of the South Armorican Shear Zone: insights for crustal-scale fluid flow and water-rock interaction processes. J Geodyn 56-57: 86–107. [Google Scholar]
  • Tiepel U, Eichhorn R, Loth G, et al. 2004. U-Pb SHRIMP and Nd isotopic data from the western Bohemian Massif (Bayerischer Wald, Germany): implications for Upper Vendian and Lower Ordovician magmatism. Int J Earth Sci 93: 782–801. [Google Scholar]
  • Thompson PH, Bard JP. 1982. Isograds and mineral assemblages in the Eastern Axial Zone, Montagne Noire (France): implications for temperature gradients and P/T history. Can J Earth Sci 19 (1): 129–143. [Google Scholar]
  • Townsend KJ, Miller CF, D’Andrea JL, et al. 2000. Low temperature replacement of monazite in the Ireteba granite, Southern Nevada: geochronological implications. Chem Geol 172: 95–112. [Google Scholar]
  • Trap P, Roger F, Cenki-Tok B, Paquette JL. 2017. Timing and duration of partial melting and magmatism in the Variscan Montagne Noire gneiss done (French Massif Central). Int J Earth Sci 106: 453–476. https://doi.org/10.1007/s00531-016-1417-x. [Google Scholar]
  • van Achterbergh E, Ryan C, Jackson S, Griffin W. 2001. Data reduction software for LA-ICP MS. In: Sylvester P, ed. Laser Ablation-ICPMS in the Earth Science, Mineralogical Association of Canada, pp. 239–243. [Google Scholar]
  • Van Den Driessche F J, Brun JP. 1989. Kinematic model of late Paleozoic extensional tectonics in the southern French Massif Central. CR Acad Sci II 309 (16): 1607–1613. [Google Scholar]
  • Van Den Driessche J, Brun JP. 1992. Tectonic evolution of the Montagne Noire (French Massif Central): a model of extensional gneiss dome. Geodin Acta 5: 85–99. [Google Scholar]
  • Van Den Driessche J, Pitra P. 2012. Viscous collision in channel explains double domes in metamorphic core complexes, Forum Comment. Geology 40 (10): E279. https://doi.org/10.1130/G32727C.1. [Google Scholar]
  • Vanderhaeghe O, Laurent O, Gardien V, et al. 2020. Flow od partially molten controlling cronstruction, growth and collapse of the Variscan orogenic belt: the geologic record of the French Massif Central. BSGF 191: 25. https://doi.org/10.1051/bsgf/2020013. [Google Scholar]
  • Whitney DL, Roger F, Teyssier C, Rey PF, Respaut JP. 2015. Syn-collapse eclogite metamorphism and exhumation of deep crust in a migmatite dome: the P-T-t record of the youngest Variscan eclogite (Montagne Noire, French Massif Central). Earth Planet Sci Lett 430: 224–234. https://doi.org/10.1016/j.epsl.2015.08.026. [CrossRef] [Google Scholar]
  • Whitney DL, Hamelin C, Teyssier C, et al. 2020. Deep crustal source of gneiss dome revealed by eclogite in migmatite (Montagne Noire, French Massif Central). J Metamorph Geol 38: 297–327. [CrossRef] [Google Scholar]
  • Williams ML, Jercinovic M, Harlov DE, Budzyn B, Hetherington CJ. 2011. Resetting monazite ages during fluid-related alteration. Chem Geol 283: 218–225. [Google Scholar]
  • Zanchetta S, Locchi S, Carminati G, Mancuso M, Montemagni C, Zanchi A. 2022. Metasomatism by Boron-Rich fluids along permian low-angle normal faults (Central Southern Alps, N Italy). Minerals 12: 404. [Google Scholar]

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