Terrestrial 10 Be and electron spin resonance dating of fluvial terraces quantifies quaternary tectonic uplift gradients in the eastern Pyrenees
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2018
- handle: 10670/1.8wb9be
- halshs: halshs-02106565
- doi: 10.1016/j.quascirev.2018.06.001
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info:eu-repo/semantics/altIdentifier/doi/10.1016/j.quascirev.2018.06.001
http://creativecommons.org/licenses/by-nc-sa/ , info:eu-repo/semantics/OpenAccess
Mots-clés
Neotectonics Pleistocene Alluvial terrace chronosequence Electron spin resonance Terrestrial cosmogenic nuclide Neotectonics Fluvial incision Topographic upliftSujets proches
Pireneus Pirineos Pyrene Pirineus Pyrenees (France and Spain) Pyrenaei MontesCiter ce document
Magali Delmas et al., « Terrestrial 10 Be and electron spin resonance dating of fluvial terraces quantifies quaternary tectonic uplift gradients in the eastern Pyrenees », Archive Ouverte d'INRAE, ID : 10.1016/j.quascirev.2018.06.001
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Résumé
The 120 km-longT^ et River flows out of the Pyrenees to the Mediterranean. By displaying a mappable sequence of Quaternary alluvial units between the Pleistocene frontal moraines of the high range and the offshore sedimentary depocentres, its 1400 km 2 watershed is well suited to quantifying gradients of topographic uplift. Five main generations of terrace treads had previously been inferred from constrasts in regolith weathering features, but here we present the first radiometric age constraints based on 15 ESR sediment burial ages covering the full sequence, and 3 vertical TCN age profiles restricted to three mid-sequence terraces. Analytically robust results were obtained for the oldest and uppermost terrace T5 (ESR age: 1099 ± 179 ka), for T3b (ESR age: 374 ± 47 ka, ~MIS 10), and for T2 (ESR age: 174 ± 44 ka, ~MIS 6). These results are consistent with the contrasts in weathering grade of the deposits. The TCN profiles only yielded minimum exposure ages but provided precise post-depositional denudation rates for the fluvial terrace treads. The land-to-sea geometry of the chronosequence also provided clues about valley incision rates in response to topographic uplift during the last ~1 Ma. Based on a critical review of similar data obtained for other Mediterranean and Atlantic watersheds in the Pyrenees, the full regional correlation reveals that post-orogenic topographic uplift was substantial and relatively uniform throughout the entire mountain range. Patterns and magnitudes suggest a shared, probably subcrustal driving mechanism of Neogene and Quaternary mountain growth, with only subsidiary influence from isostasy, and climatic forcing.