Deciphering the Cenozoic exhumation history of the Eastern Pyrenees along a crustal-scale normal fault using low-temperature thermochronology

Milesi, Gaétan; Monié, Patrick; Soliva, Roger; Münch, Philippe; Valla, Pierre G.; Brichau, Stéphanie; Bonno, Michaël; Martin, Céline; Bellanger, Mathieu

doi:10.1002/essoar.10510891.1

Cited by 3 publications

(25 citation statements)

References 82 publications

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“…Contemporaneously, normal faulting in the eastern end of the Axial Zone began at 35 Ma, further suggesting a latest Eocene shift in the dynamics of the range (Milesi et al., 2022). The eastern end of the range records localized extension within the Axial Zone, related to the opening of the Gulf of Lyon, evidenced by modeling of 43–18 Ma apatite (U‐Th)/He cooling ages sampled across the Têt normal nault (Milesi et al., 2022). No similar late Eocene extension has been documented in the central or western portions of the range.…”

Section: Discussionmentioning

confidence: 99%

“…The coeval ages of thrusting on many faults in multiple regions of the Pyrenees during the Middle and Late Eocene demonstrate that the range effectively behaved as a doubly tapered critical wedge, analogous to the no‐backstop critical wedge model (sensu Dahlen et al., 1984). Contemporaneously, normal faulting in the eastern end of the Axial Zone began at 35 Ma, further suggesting a latest Eocene shift in the dynamics of the range (Milesi et al., 2022). The eastern end of the range records localized extension within the Axial Zone, related to the opening of the Gulf of Lyon, evidenced by modeling of 43–18 Ma apatite (U‐Th)/He cooling ages sampled across the Têt normal nault (Milesi et al., 2022).…”

Section: Discussionmentioning

confidence: 99%

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Fault Gouge Dating in the Spanish Pyrenees: Fault Ages, Thrust Propagation Sequence, Wall‐Rock Provenance, and Thermal Constraints

Haines

Pluijm

2023

Tectonics

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Dating brittle faults by the growth of authigenic illite in fault gouge allows for direct testing of kinematic models of orogenic evolution, such as in‐sequence versus out‐of‐sequence thrusting, and the presence of orogenic “pulses” of deformation on multiple thrusts simultaneously. We present illite gouge ages from five thrust faults along the Ter and Freser rivers in the south‐eastern Pyrenees fold‐and‐thrust belt dated by Ar‐Ar methods. The ages show in‐sequence thrusting for the south‐eastern Pyrenees fold‐thrust belt during the Eocene and early Oligocene, ranging from 49.5 + 4.4 Ma for the inboard Freser Antiformal Stack to 31.9 ± 3.9 Ma for the frontal L’Escala Thrust. Foreland progression of ages is preserved, although overlapping of ages of the frontal thrusts permits the interpretation of a period of more rapid fault displacement around 35 Ma. Shortening rates for the Ter‐Freser section range from 1.2–2.7 km/my, with strain rates ranging from 7.0 × 10−16 s−1 to 1.6 × 10−15 s−1 The latest Paleozoic ages of the cataclastically derived component inferred from the gouge dating methodology are shown to be pooled 2M1 illite/mica ages of wall rock sediments and have geological meaning. These inferred mica ages of the thrust wallrocks in the southeastern Pyrenees indicate Hercynian‐age micas were deposited in the Southern Pyrenean foreland basin as early as the late Cretaceous. Previous thermochronometer and Δ47 temperatures from syn‐faulting calcite veins constrain temperature of clay gouge formation in the Ter‐Freser section at 50–210°C, with most likely temperatures of 50–160°C, consistent with previous studies.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Fault Gouge Dating in the Spanish Pyrenees: Fault Ages, Thrust Propagation Sequence, Wall‐Rock Provenance, and Thermal Constraints

Haines

Pluijm

2023

Tectonics

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“…Low-temperature thermochronometric studies often emphasize one or more tectonic phases as the cause of accelerated exhumation and highlight the role of major faults. The combined use of thermochronometric tools and fault gouge dating allows the age of fault activity to be better constrained [Duvall et al, 2011, Münch et al, 2021, Milesi et al, 2022, Parry et al, 2001, Tagami, 2012.…”

Section: Age Interpretationmentioning

confidence: 99%

40 Ar/ 39 Ar geochronology of crustal deformation

Monié,

Münch,

Milesi

et al. 2024

Comptes Rendus. Géoscience

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Crustal deformation is characterized by brittle and ductile faults that accommodate at different scales the strain imposed by plate tectonics. The aim of this contribution is to show with the help of different examples how the in situ 40 Ar/ 39 Ar dating of synkinematic neocrystallized minerals in ductile shear zones and the step-heating 40 Ar/ 39 Ar dating of synkinematic authigenic clays in fault gouges can bring information on the timing of fault activity. However, due to their complex evolution, interpretation of the argon signature in fault zones requires consideration of several effects among which re-or neocrystallization, inheritance and fluid interaction processes are dominant.

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“…Moreover, these previous studies have been particularly focused on the Paleogene Pyrenean contractional phase. The Eastern Pyrenees have a specific evolution, reflected by a complex tectonic history with an Eocene contractional phase (Laumonier, 2015;Ternois et al, 2019;Calvet et al, 2021;Ford et al, 2022) followed by 2 significant post-orogenic periods: i) a transtensionnal phase associated with the opening of the West European Rift (Angrand and Mouthereau, 2021;Milesi et al, 2022), and ii) an Oligocene-Miocene extensional phase associated to the Gulf of Lion opening (Calvet et al, 2021;2020Romagny et al, 2020;Séranne et al, 2021;Taillefer et al, 2021;Milesi et al, 2022). The Têt normal fault is the most prominent tectonic structure in the Eastern Pyrenees, and localizes high-relief massifs in such as the Mont-Louis (hanging wall), and the Canigou and Carança (footwall) massifs.…”

Section: Introductionmentioning

confidence: 99%

“…The development of these high topographic reliefs has been related to normal faulting during the Oligocene-Miocene period (Maurel et al, 2008, Milesi et al, 2022. However, the topographic evolution of the area is still highly debated (e.g.…”

Section: Introductionmentioning

confidence: 99%

Tectono-geomorphological evolution of the Eastern Pyrenees: Insights from thermo-kinematic modeling

Milesi,

Valla,

Münch

et al. 2023

Tectonophysics

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Deciphering the Cenozoic exhumation history of the Eastern Pyrenees along a crustal-scale normal fault using low-temperature thermochronology

Abstract: In orogenic belts, crustal-scale faults are key deformation markers that accommodate various regimes of plate tectonics during rock burial, exhumation or strike slip activity (

Cited by 3 publications

References 82 publications

Fault Gouge Dating in the Spanish Pyrenees: Fault Ages, Thrust Propagation Sequence, Wall‐Rock Provenance, and Thermal Constraints

Fault Gouge Dating in the Spanish Pyrenees: Fault Ages, Thrust Propagation Sequence, Wall‐Rock Provenance, and Thermal Constraints

40 Ar/ 39 Ar geochronology of crustal deformation

Tectono-geomorphological evolution of the Eastern Pyrenees: Insights from thermo-kinematic modeling

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