Weak orogenic lithosphere guides the pattern of plume-triggered supercontinent break-up

The importance of nonrigid geological features (such as orogens) inside tectonic plates on Earth’s dynamic evolution lacks thorough investigation. In particular, the influence of continent-spanning orogens on (super)continental break-up remains unclear. Here we reconstruct global orogens and model t...

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Veröffentlicht in:Communications earth & environment 2020-11, Vol.1 (1), Article 51
Hauptverfasser: Dang, Zhuo, Zhang, Nan, Li, Zheng-Xiang, Huang, Chuan, Spencer, Christopher J., Liu, Yebo
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Sprache:eng
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Zusammenfassung:The importance of nonrigid geological features (such as orogens) inside tectonic plates on Earth’s dynamic evolution lacks thorough investigation. In particular, the influence of continent-spanning orogens on (super)continental break-up remains unclear. Here we reconstruct global orogens and model their controlling effects on Pangea break-up. We show that while loci of Pangea break-up are linked to mantle plumes, development of continental rifts is guided by orogens. Rifting at Central Atlantic is driven by the modelled plume responsible for the Central Atlantic Magmatic Province (CAMP) within Pangea-forming orogens. South Atlantic rifting is controlled by necking between Pangea- and Gondwana-forming orogens with the assistance of plume-induced lithospheric weakening. Without CAMP-induced weakening, South Atlantic rifting fails between the West African and Amazonian cratons, but occurs between the West African and Saharan cratons instead. Our modeling on Pangea break-up is able to recreate present-day continental geometry through the combined effect of orogens and plume center-locations. The location of orogenic belts has a strong influence on the rifting of supercontinents after mantle plumes trigger the initial break-up and contribute to lithospheric weakening, according to numerical simulations of the break-up of Pangea.
ISSN:2662-4435
2662-4435
DOI:10.1038/s43247-020-00052-z