Mantle evolution in the Variscides of SW England: Geochemical and isotopic constraints from mafic rocks

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• 作者：Nicolle E. Dupuis^a ; ^{nicolle.dupuis@gmail.com" class="auth_mail" title="E-mail the corresponding author} ; J. Brendan Murphy^a ; James A. Braid^a ; Robin K. Shail^b ; R. Damian Nance^c
• 关键词：Lamprophyre ; Variscides ; Continental collision ; Postcollisional magmatism ; Mantle evolution ; Pangea
• 刊名：Tectonophysics
• 出版年：2016
• 出版时间：20 June 2016
• 年：2016
• 卷：681
• 期：Complete
• 页码：353-363
• 全文大小：2160 K

文摘

The geology of SW England has long been interpreted to reflect Variscan collisional processes associated with the closure of the Rhenohercynian Ocean and the formation of Pangea. The Cornish peninsula is composed largely of Early Devonian to Late Carboniferous volcanosedimentary successions that were deposited in pre- and syn-collisional basins and were subsequently metamorphosed and deformed during the Variscan orogeny. Voluminous Early Permian granitic magmatism (Cornubian Batholith) is broadly coeval with the emplacement of ca. 280–295 Ma lamprophyric dykes and flows. Although these lamprophyres are well mapped and documented, the processes responsible for their genesis and their relationship with regional Variscan tectonic events are less understood.

Pre- to syn-collisional basalts have intra-continental alkalic affinities, and have REE profiles consistent with derivation from the spinel–garnet lherzolite boundary. εNd values for the basalts range from + 0.37 to + 5.2 and TDM ages from 595 Ma to 705 Ma. The lamprophyres are extremely enriched in light rare earth elements, large iron lithophile elements, and are depleted in heavy rare earth elements, suggesting a deep, garnet lherzolite source that was previously metasomatised. They display εNd values ranging from − 1.4 to + 1.4, initial Sr values of ca. 0.706, and TDM ages from 671 Ma to 1031 Ma, suggesting that metasomatism occurred in the Neoproterozoic.

Lamprophyres and coeval granite batholiths of similar chemistry to those in Cornwall occur in other regions of the Variscan orogen, including Iberia and Bohemia. By using new geochemical and isotopic data to constrain the evolution of the mantle beneath SW England and the processes associated with the formation of these post-collisional rocks, we may be able to gain a more complete understanding of mantle processes during the waning stages of supercontinent formation.