Eocene high-K magmatic flare-up in a context of south dipping subduction and strike-slip tectonics: Insights from the Talysh Massif, NW Iran

Abstract

The geodynamic significance of Cenozoic magmatism of the Central Tethyan orogenic belt linking the tectonic zones of Iran, South Armenian Block (Lesser Caucasus) and Turkey remains a subject of debate. This study is focused on the thick geological succession of high potassic magmatic rocks erupted in Talysh Massif, NW Iran. We report a comprehensive geochemical study that demonstrates that this succession is comprised of shoshonitic mostly basaltic and some rhyolitic pyroclastic rocks emplaced during an Eocene magmatic flare-up. Forsterite rich olivine (Fo 70–93), combined to high-Mg clinopyroxene (Mg# 0.6–0.8) and high-Ti calcic amphibole (magnesiohastingsite) are the dominant mafic minerals in these rocks. Mafic lavas are enriched in LILE and depleted in HFSE, with high Th/Yb, Ba/Th and Nb/Zr ratios, suggestive of an enriched mantle source following Tethys subduction history. Interlayered felsic lavas allowed to date the series by U-Pb on zircon at 43.17 ± 0.40 Ma, with one relict core displaying an inherited age of 580 Ma. eHfi CHUR of Eocene zircons range from 1.7 to −0.9 (with corresponding TDM ages around 1.0 Ga). The latter, along with the detection of a Neoproterozoic zircon xenocryst, indicates a crustal contamination by a Neoproterozoic (and older) lower crust. These data are in agreement with the partial melting of a subduction-modified subcontinental mantle. This magmatic flare-up could have been triggered by an Asthenosphere upwelling related to the onset of south-dipping subduction in the Transcaucasus region and transcrustal strike-slip faults with a more significant crustal contamination than in the Lesser Caucasus region.