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Ascent-driven differentiation: a mechanism to keep arc magmas metaluminous?

Felix Marxer, Peter Ulmer, Othmar Müntener

2023Contributions to Mineralogy and Petrology21 citationsDOIOpen Access PDF

Abstract

Abstract Arc magmatism is fundamental to the generation of new continental or island arc crust. However, the mechanisms that add to the chemical complexity of natural calc-alkaline magmas ranging from basaltic to rhyolitic compositions are debated. Differentiation mechanisms currently discussed include magma mixing, assimilation, crustal melting, or (fractional) crystallisation. In this contribution, the differentiation of arc magmas by decompression-driven crystallisation is investigated. We performed a set of equilibrium crystallisation experiments at variable crustal pressures (200–800 MPa) on a hydrous high-Al basalt (3.5 wt.% of H 2 O in the starting material) with run temperatures varying from near-liquidus conditions (1110 °C) to 900 °C. Oxygen fugacity was buffered at moderately oxidising conditions close to the NNO equilibrium. Combining these novel experiments with previous polybaric fractional crystallisation experiments (Marxer et al., Contrib Mineral Petrol 177:3, 2022) we demonstrate the effects of pressure on the crystallisation behaviour of calc-alkaline magmas with respect to liquid and cumulate lines of descent, mineral chemistry, and phase proportions. Decompression shifts the olivine-clinopyroxene cotectic curve towards melt compositions with higher normative clinopyroxene and enlarges the stability field of plagioclase. This exerts a key control on the alumina saturation index of residual liquids. We argue that near-adiabatic (or near-isothermal) decompression accompanied by dissolution of clinopyroxene entrained during residual melt extraction in the lower crust keeps arc magmas metaluminous during crystallisation-driven differentiation thereby closely reproducing the compositional spread observed for natural arc rocks.

Topics & Concepts

Fractional crystallization (geology)Igneous differentiationGeologyMineral redox bufferLiquidusGeochemistryCrustMantle (geology)BiotiteChemistryPhase (matter)QuartzPaleontologyOrganic chemistryGeological and Geochemical AnalysisHigh-pressure geophysics and materialsearthquake and tectonic studies
Ascent-driven differentiation: a mechanism to keep arc magmas metaluminous? | Litcius