The list below shows Durham University research staff who are members of IMEMS. Click the member's name to see a more detailed biography and department.
We also welcome anyone from outside the University with an interest in our work to join. Membership is free of charge. You will receive invitations to our programme of events, with a weekly emails digest about what is happening in the Insitute and further afield. To join IMEMS contact: firstname.lastname@example.org
Publication details for Prof Mark AllenNeill, I., Meliksetian, Kh., Allen, M.B., Navasardyan, G. & Karapetyan, S. (2013). Pliocene-Quaternary volcanic rocks of NW Armenia: Magmatism and lithospheric dynamics within an active orogenic plateau. Lithos 180-181: 200-215.
- Publication type: Journal Article
- ISSN/ISBN: 0024-4937 (print)
- DOI: 10.1016/j.lithos.2013.05.005
- Keywords: Armenia, Geochemistry, Petrogenesis, Orogenic plateau.
- Further publication details on publisher web site
- Durham Research Online (DRO) - may include full text
Author(s) from Durham
The Pliocene–Quaternary volcanic rocks of Armenia are a key component of the Arabia–Eurasia collision, representing intense magmatism within the Turkish–Iranian plateau, tens of millions of years after the onset of continental collision. Here we present whole rock elemental and Ndsingle bondSr isotope data from mafic, intermediate, and felsic lava flows and cinder cones in Shirak and Lori provinces, NW Armenia. Magmatism appears to be controlled locally by extension related to major strike-slip faults within the plateau. Major and trace element results show that the three series—valley-filling medium-K alkali basalt flows, ridge-forming andesite to rhyolite flows, and andesitic cinder cones—form a compositional continuum linked by a crystallisation sequence dominated by two pyroxenes, plagioclase and amphibole. There is petrographic and major and trace element evidence for magma mixing processes and potentially crustal contamination by Mesozoic–early Cenozoic arc-related rocks, which has not significantly affected the isotopic signature. Modelling of the basaltic rocks indicates that they formed by moderate degrees of partial melting (~ 3–4%) of an incompatible element enriched, subduction-modified, lithospheric mantle source. Samples have a distinctive high Zr/Hf ratio and high Zr concentrations, which are an intrinsic part of the source or the melting process, and are much more commonly found in ocean island basalts. Regional models for magmatism often argue for whole-scale delamination of the mantle lithosphere beneath Eastern Anatolia and the Lesser Caucasus, but this scenario is hard to reconcile with limited crustal signatures and the apparent lack of asthenospheric components within many studied centres.