In this study, we present new mineralogical and petrological data from fifteen eruptive products erupted at Vulcano Island (Aeolian Arc, Italy) over a period of time from 54 to 8 ka and representative of the Eruptive Epochs from 5 to 8 of this volcanic system. These rocks show shoshonitic (SHO) to high-K calc-alkaline (HKCA) affinity, with compositions changing from primitive basalts-shoshonites (Mg#35-60) to intermediate latites (Mg#32-54) to evolved trachytes-rhyolites (Mg#23-40). The intensive variables driving the crystallization path of magmas were reconstructed through mineral-melt equilibrium and thermodynamic models, as well as barometers, thermometers, hygrometers and oxygen barometers. The stability of olivine (Fo59-91), as first phase on the liquidus, is more favored at low-P (100-300 MPa) and high-H2O (4 wt.%) contents dissolved in the melt. Afterwards, the melt is co-saturated with clinopyroxene (Mg#92, diopside), whose composition progressively evolves (Mg#71, augite) as the temperature decreases to 1100 °C. The crystallization pressure recorded by clinopyroxene decreases from basalts (550-750 MPa) to shoshonites-latites-trachytes (100-450 MPa) to rhyolites (~50 MPa). The melt-H2O content (0.5-4.2 wt.%) is sensitive to either pressure or melt composition, thereby controlling the plagioclase stability and chemistry (An13-77) within a thermal path of ~860-1100 °C. Titanomagnetite (Usp11-39) equilibrates with progressively more oxidized melts as the magma composition changes from basalt (ΔQFM+1.5) to rhyolite (ΔQFM+3). Mass balance calculations and trace element modeling indicate that basaltic to trachytic magmas are prevalently controlled by fractional crystallization processes, in concert with variable degrees of assimilation of crustal rocks. Conversely, rhyolitic and highly differentiated trachytic magmas are generated by extraction of interstitial melts from shallow mush zones dominated by feldspar and titanomagnetite saturation. We conclude that the architecture of the plumbing system at Vulcano Island is characterized by multiple reservoirs in which compositionally distinct magmas pond and undergo polybaric-polythermal differentiation, before erupting to the surface.

Reconstruction of the intensive variables and magmatic architecture of Vulcano Island (Aeolian Arc, Italy) / Palummo, Flavia. - (2022 Mar 24).

Reconstruction of the intensive variables and magmatic architecture of Vulcano Island (Aeolian Arc, Italy)

PALUMMO, FLAVIA
24/03/2022

Abstract

In this study, we present new mineralogical and petrological data from fifteen eruptive products erupted at Vulcano Island (Aeolian Arc, Italy) over a period of time from 54 to 8 ka and representative of the Eruptive Epochs from 5 to 8 of this volcanic system. These rocks show shoshonitic (SHO) to high-K calc-alkaline (HKCA) affinity, with compositions changing from primitive basalts-shoshonites (Mg#35-60) to intermediate latites (Mg#32-54) to evolved trachytes-rhyolites (Mg#23-40). The intensive variables driving the crystallization path of magmas were reconstructed through mineral-melt equilibrium and thermodynamic models, as well as barometers, thermometers, hygrometers and oxygen barometers. The stability of olivine (Fo59-91), as first phase on the liquidus, is more favored at low-P (100-300 MPa) and high-H2O (4 wt.%) contents dissolved in the melt. Afterwards, the melt is co-saturated with clinopyroxene (Mg#92, diopside), whose composition progressively evolves (Mg#71, augite) as the temperature decreases to 1100 °C. The crystallization pressure recorded by clinopyroxene decreases from basalts (550-750 MPa) to shoshonites-latites-trachytes (100-450 MPa) to rhyolites (~50 MPa). The melt-H2O content (0.5-4.2 wt.%) is sensitive to either pressure or melt composition, thereby controlling the plagioclase stability and chemistry (An13-77) within a thermal path of ~860-1100 °C. Titanomagnetite (Usp11-39) equilibrates with progressively more oxidized melts as the magma composition changes from basalt (ΔQFM+1.5) to rhyolite (ΔQFM+3). Mass balance calculations and trace element modeling indicate that basaltic to trachytic magmas are prevalently controlled by fractional crystallization processes, in concert with variable degrees of assimilation of crustal rocks. Conversely, rhyolitic and highly differentiated trachytic magmas are generated by extraction of interstitial melts from shallow mush zones dominated by feldspar and titanomagnetite saturation. We conclude that the architecture of the plumbing system at Vulcano Island is characterized by multiple reservoirs in which compositionally distinct magmas pond and undergo polybaric-polythermal differentiation, before erupting to the surface.
24-mar-2022
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1623398
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