Mesozoic marine reptile palaeobiogeography in response to drifting plates

peer reviewed During the Mesozoic, various groups of reptiles underwent a spectacular return to an aquatic life, colonizing most marine environments. They were highly diversified both systematically and ecologically, and most were the largest top-predators of the marine ecosystems of their time. The...

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Bibliographic Details
Published in:Gondwana Research
Main Authors: Bardet, Nathalie, Falconnet, Jocelyn, Fischer, Valentin, Houssaye, Alexandra, Jouve, Stéphane, Pereda-Superbiola, Xavier, Perez-García, Adan, Rage, Jean-Claude, Vincent, Peggy
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier 2014
Subjects:
Palaeobiogeography
Plate tectonics
Marine reptiles
Ichthyosauria
Plesiosauria
Crocodyliforms
Mosasaurs
Pythonomorpha
Aquatic
Physical
chemical
mathematical & earth Sciences
Earth sciences & physical geography
Physique
chimie
mathématiques & sciences de la terre
Sciences de la terre & géographie physique
North Atlantic
Online Access:https://orbi.uliege.be/handle/2268/168688
https://orbi.uliege.be/bitstream/2268/168688/1/Bardet%20et%20al%20In%20Press%20Mesozoic%20marine%20reptile%20palaeobiogeography%20in%20response%20to%20drifting%20plates.pdf
https://doi.org/10.1016/j.gr.2014.05.005
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Summary:peer reviewed During the Mesozoic, various groups of reptiles underwent a spectacular return to an aquatic life, colonizing most marine environments. They were highly diversified both systematically and ecologically, and most were the largest top-predators of the marine ecosystems of their time. The main groups were Ichthyosauria, Sauropterygia, Thalattosauria, and several lineages of Testudinata, Crocodyliformes, Rhynchocephalia and Squamata. Here we show that the palaeobiogeographical distribution of these marine reptiles closely followed the break-up of the supercontinent Pangaea and that they globally used the main marine corridors created by this break-up to disperse. Most Mesozoic marine reptile clades exhibit a cosmopolitan, or at least pandemic, distribution very early in their evolutionary history. The acquisition of morphological adaptations to a fully aquatic life, combined to special thermophysiological characteristics, are probably responsible for these animals to become efficient long-distance open-marine cruisers. Generally, Early Triassic taxa were near-shore animals mainly linked to the Tethys or Panthalassa coastlines. By the end of the Triassic and during the Jurassic, the break-up of Pangaea resulted in the formation of large marine corridors connecting the Tethys to the North Atlantic and Pacific realms, a trend increasing on during the Cretaceous with the expansion of the Atlantic Ocean and the break-up of the southern Gondwana, allowing open-sea marine reptiles to spread out over large distances. However, if large faunal interchanges were possible at a global scale following a dispersal model, some provinces, such as the Mediterranean Tethys, were characterized by a peculiar faunal identity, illustrating an absence of migration with time despite the apparent lack of barriers. So, if Continental Drift enabled global circulations and faunal interchanges via dispersals among Mesozoic marine reptiles, others parameters, such as ecological and biological constraints, probably also played a ...

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