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Quantification of vertical movement of low elevation topography combining a new compilation of global sea-level curves and scattered marine deposits (Armorican Massif, western France)

Urheber*innen

Bessin,  P.
External Organizations;

Guillocheau,  F.
External Organizations;

Robin,  C.
External Organizations;

/persons/resource/jbraun

Braun,  Jean
5.5 Earth Surface Process Modelling, 5.0 Geoarchives, Departments, GFZ Publication Database, Deutsches GeoForschungsZentrum;

Bauer,  H.
External Organizations;

Schroëtter,  J.-M.
External Organizations;

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Zitation

Bessin, P., Guillocheau, F., Robin, C., Braun, J., Bauer, H., Schroëtter, J.-M. (2017): Quantification of vertical movement of low elevation topography combining a new compilation of global sea-level curves and scattered marine deposits (Armorican Massif, western France). - Earth and Planetary Science Letters, 470, 25-36.
https://doi.org/10.1016/j.epsl.2017.04.018


Zitierlink: https://gfzpublic.gfz-potsdam.de/pubman/item/item_2338894
Zusammenfassung
A wide range of methods are available to quantify Earth's surface vertical movements but most of these methods cannot track low amplitude (<1 km, e.g. thermochronology) or old (>5 Ma, e.g. cosmogenic isotope studies) vertical movements characteristic of plate interiors. The difference between the present-day elevation of ancient sea-level markers (deduced from well dated marine deposits corrected from their bathymetry of deposition) and a global sea-level (GSL) curve are sometimes used to estimate these intraplate vertical movements. Here, we formalized this method by re-assessing the reliability of published GSL curves to build a composite curve that combines the most reliable ones at each stage, based on the potential bias and uncertainties inherent to each curve. We suggest i) that curves which reflect ocean basin volume changes are suitable for the ca. 100 to 35 Ma “greenhouse” period ii) whereas curves that reflects ocean water volume changes are better suited for the ca. 35 to 0 Ma “icehouse” interval and iii) that, for these respective periods, the fit is best when using curves that accounts for both volume changes. We used this composite GSL curve to investigate the poorly constrained Paleogene to Neogene vertical motions of the Armorican Massif (western France). It is characterized by a low elevation topography, a Variscan basement with numerous well dated Cenozoic marine deposits scattered upon it. Using our method, we identify low amplitude vertical movements ranging from 66 m of subsidence to 89 m of uplift over that time period. Their spatial distribution argues for a preferred scale of deformation at medium wavelengths (i.e., order 100 km), which we relate to the deformation history of northwestern European lithosphere in three distinct episodes. i) A phase of no deformation between 38 and 34 Ma, that has been previously recognized at the scale of northwestern Europe, ii) a phase of low subsidence between 30 and 3.6 Ma, possibly related to buckling of the lithosphere and iii) a phase of more pronounced uplift between 2.6 Ma and present, which we relate to the acceleration of the Africa–Apulia convergence or to enhanced erosion in the rapidly cooling climate of the Pleistocene.