Liquidus Equilibria in the System K2O-Na2O-Al2O3-SiO2-F2O-1-H2O to 100 MPa: I. Silicate-Fluoride Liquid Immiscibility in Anhydrous Systems |
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Authors: | DolejS David; Baker Don R |
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Institution: | Department of Earth and Planetary Sciences, Mcgill University, Montreal, QC H3A 2A7, Canada |
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Abstract: | Liquidus relations in the four-component system Na2OAl2O3SiO2F2O1were studied at 0· 1 and 100 MPa to define the locationof fluoridesilicate liquid immiscibility and outlinedifferentiation paths of fluorine-bearing silicic magmas. Thefluoridesilicate liquid immiscibility spans the silicaalbitecryoliteand silicatopazcryolite ternaries and the haplogranite-cryolitebinary at greater than 960°C and 0· 1100 MPa.With increasing Al2O3 in the system and increasing aluminum/alkalication ratio, the two-liquid gap contracts and migrates fromthe silica liquidus to the cryolite liquidus. The gap does notextend to subaluminous and peraluminous melt compositions. Forall alkali feldsparquartz-bearing systems, the miscibilitygap remains located on the cryolite liquidus and is thus inaccessibleto differentiating granitic and rhyolitic melts. In peralkalinesystems, the magmatic differentiation is terminated at the albitequartzcryoliteeutectic at 770°C, 100 MPa, 5 wt % F and cation Al/Na =0· 75. The addition of topaz, however, significantlylowers melting temperatures and allows strong fluorine enrichmentin subaluminous compositions. At 100 MPa, the binary topazcryoliteeutectic is located at 770°C, 39 wt % F, cation Al/Na 0·95, and the ternary quartztopazcryolite eutecticis found at 740°C, 32 wt % F, 30 wt % SiO2 and cation Al/Na 0· 95. Such location of both eutectics enables fractionationpaths of subaluminous quartz-saturated systems to produce fluorine-rich,SiO2-depleted and nepheline-normative residual liquids. KEY WORDS: silicate melt; granite; rhyolite; fluorine; liquid immiscibility |
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Keywords: | : silicate melt granite rhyolite fluorine liquid immiscibility |
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