The Evolution of the Rheic Ocean: From Avalonian-Cadomian Active Margin to Alleghenian-Variscan Collision
The diversity and geodynamic significance of Late Cambrian (ca. 500 Ma) felsic anorogenic magmatism in the northern part of the Bohemian Massif: A review based on Sm-Nd isotope and geochemical data
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Published:January 01, 2007
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CiteCitation
Christian Pin, R. Kryza, T. Oberc-Dziedzic, S. Mazur, K. Turniak, Jarmila Waldhausrová, 2007. "The diversity and geodynamic significance of Late Cambrian (ca. 500 Ma) felsic anorogenic magmatism in the northern part of the Bohemian Massif: A review based on Sm-Nd isotope and geochemical data", The Evolution of the Rheic Ocean: From Avalonian-Cadomian Active Margin to Alleghenian-Variscan Collision, Ulf Linnemann, R. Damian Nance, Petr Kraft, Gernold Zulauf
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Ca. 500 Ma orthogneisses and bimodal suites are widespread along the northern part of the Bohemian Massif (central European Variscides) and are interpreted to document intense magmatism during a continental break-up episode along the northern periphery of Gondwana. Based on geological setting, and geochemical and isotopic evidence, these felsic igneous rocks record the generation of: (1) magmas of pure or predominantly crustal derivation, represented by minor extrusives and much more voluminous orthogneisses similar to S-type granitoids; (2) subordinate magmas of exclusively mantle origin (ranging from within-plate alkali trachytes to oceanic plagiogranites) corresponding to felsic derivatives of associated basalts; and (3) magmas of hybrid origin, produced either as a result of large degrees of contamination of mantle-derived magmas ascending through the crust, or alternatively, generated by partial melting of mixed sources, such as interlayered sediments and mafic rocks or graywackes containing a juvenile component. The high-temperature dehydration melting process responsible for the generation of the most abundant rock-types necessitated the advection of mantle heat, in a context of continental lithosphere extension, as documented by broadly coeval basaltic magmatism at the scale of the igneous province. The large volumes of felsic magmas generated during the 500-Ma anorogenic event are interpreted to result from the combination of a hot extensional tectonic regime with the widespread availability in the lower crust of fertile lithologies, such as metagraywackes. This in turn reflects the largely undifferentiated nature of the crustal segment accreted some 50–100 m.y. earlier during the Cadomian orogeny.
- A-type granites
- basalts
- Bohemian Massif
- Cadomian Orogeny
- Cambrian
- Central Europe
- chemical composition
- crust
- Czech Erzgebirge
- Czech Republic
- Czech Sudeten Mountains
- diorites
- Erzgebirge
- Europe
- felsic composition
- Fichtelgebirge
- geochemistry
- geodynamics
- gneisses
- granites
- igneous rocks
- isotope ratios
- isotopes
- lithosphere
- lower crust
- magmatism
- mantle
- metals
- metamorphic rocks
- mineral composition
- Nd-144/Nd-143
- neodymium
- orthogneiss
- Paleozoic
- petrology
- plagiogranite
- plutonic rocks
- rare earths
- Saxothuringian
- stable isotopes
- Sudeten Mountains
- trachytes
- Upper Cambrian
- volcanic rocks
- Kaczawa Complex
- Izera-Karkonosze Massif
- Orlica-Snieznik Massif
- Gory Sowie Massif
- Vesser Czech Republic
- Krivoklat-Rokycany Complex