Abstract
The generation of strongly potassic melts in the mantle requires the presence of phlogopite in the melting assemblage, while isotopic and trace element analyses of ultrapotassic rocks frequently indicate the involvement of subducted crustal lithologies in the source. However, phlogopite-free experiments that focus on melting of sedimentary rocks and subsequent hybridization with mantle rocks at pressures of 1–3 GPa have not successfully produced melts with K2O >5 wt%–6 wt%, while ultrapotassic igneous rocks reach up to 12 wt% K2O. Accordingly, a two-stage process that enriches K2O and increases K/Na in intermediary assemblages in the source prior to ultrapotassic magmatism seems likely. Here, we simulate this two-stage formation of ultrapotassic magmas using an experimental approach that involves re-melting of parts of an experimental product in a second experiment. In the first stage, reaction experiments containing layered sediment and dunite produced a modally metasomatized reaction zone at the border of a depleted peridotite. For the second-stage experiment, the metasomatized dunite was separated from the residue of the sedimentary rock and transferred to a smaller capsule, and melts were produced with 8 wt%–8.5 wt% K2O and K/Na of 6–7. This is the first time that extremely K-enriched ultrapotassic melts have been generated experimentally from sediments at low pressure applicable to a post-collisional setting.
Highlights
ARC Centre of Excellence of Core to Crust Fluid Systems and Department of Earth and Planetary Sciences, Institute für Geowissenschaften, Johannes Gutenberg Universität, 55099 Mainz, Germany; State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences, Faculty of Mining and Geology, University Belgrade, Đušina 7, 11000 Belgrade, Serbia
“Alkaline igneous rocks” is an umbrella term describing all igneous rocks that are generally enriched in the oxide species Na2 O and K2 O relative to sub-alkaline rocks at similar
K2 O has to be enriched at source, and the isotopic compositions of most potassic alkaline magmas probably lie within the metasomatically overprinted lithospheric mantle
Summary
For the second-stage experiment, the metasomatized dunite was separated from the residue of the sedimentary rock and transferred to a smaller capsule, and melts were produced with 8 wt%–8.5 wt% K2 O and K/Na of 6–7 This is the first time that extremely K-enriched ultrapotassic melts have been generated experimentally from sediments at low pressure applicable to a post-collisional setting. These phlogopite-rich “metasomes” may be pyroxenites or glimmerites, most likely formed when K-rich liquids react with peridotite to form layers and veins [12,13,14]. This explanation often does not specify the ultimate origin of the glimmeritic metasomes or the K-rich liquids that generated them
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