Mineral-Melt Equilibria and Geothermobarometry of Campi Flegrei Magmas: Inferences for Magma Storage Conditions

Pelullo, Carlo; Iovine, Raffaella Silvia; Arienzo, Ilenia; Renzo, Valeria Di; Pappalardo, Lucia; Petrosino, Paola; D’Antonio, Massimo

doi:10.3390/min12030308

Cited by 12 publications

(3 citation statements)

References 160 publications

(334 reference statements)

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“…Large, explosive volcanic eruptions demonstrate that the crust must create and accommodate large volumes of melt-dominated magma prior to eruption. Substantial advances have been made to understand the pre-eruptive conditions of the melt-dominated magma bodies that feed such eruptions (Cashman & Giordano, 2014), including crystallization timescales (Simon and Reid, 2005;Charlier et al, 2008;Druitt et al, 2012;Allan et al, 2013;Barboni and Schoene, 2014;Chamberlain et al, 2014;Cooper and Kent, 2014;Pamukçu et al, 2015a;Gualda and Sutton, 2016;Fabbro et al, 2017;Reid and Vazquez, 2017;Shamloo and Till, 2019;Chakraborty and Dohmen, 2022); storage pressures (Blundy and Cashman, 2008;Hansteen and Klügel, 2008;Putirka, 2008;Ridolfi et al, 2010;Gualda and Ghiorso, 2013a;Bégué et al, 2014a;Bachmann and Huber, 2016;Gualda et al, 2018;Pitcher et al, 2021;Pelullo et al, 2022); volatile content (Moore et al, 1998;Papale et al, 2006;Ghiorso and Gualda, 2015;Waters and Lange, 2015;Iacovino et al, 2021;Wieser et al, 2022); and oxygen fugacity (fO2) conditions (McCanta et al, 2004;Kelley and Cottrell, 2009;Ulmer et al, 2018;Pitcher et al, 2021;Ghiorso et al, 2023). These eruptions have a variety of possible pre-eruptive storage configurations as they can erupt from one magma body, as in the 'mush' model…”

Section: Introductionmentioning

confidence: 99%

The Whakamaru Magmatic System (Taupō Volcanic Zone, New Zealand), Part 2: Evidence from ignimbrite deposits for pre-eruptive distribution of melt-dominated magma and magma mushes

Harmon,

Smithies,

Gualda

et al. 2024

Preprint

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The Whakamaru volcanic deposits in Aotearoa New Zealand make up the largest eruptions in the young Taupō Volcanic Zone (TVZ). The complex volcanology and petrology of the multiple mappable ignimbrite units have obscured the number of eruptive phases, the relative timing of these eruption(s), and the pre-eruptive conditions of the magma bodies. To address these complexities, we use pumice clasts from multiple ignimbrite localities in conjunction with tephra deposits (Harmon et al., Part 1). Analysis of whole-rock and glass compositions from individual pumice clasts reveals the different magma types that participated in the eruptions. We confirm four main types of magma (types A, B, C, D; originally identified by Brown et al., 1998), which likely represent independent magma bodies. By examining the distribution of magma types in the ignimbrite record and corresponding tephra record (Harmon et al., Part 1), we establish the sequence of eruption for the four different mappable ignimbrites. The ignimbrites to the east of the caldera (Rangitaiki ± Te Whaiti) erupted before the Whakamaru ignimbrite (sensu stricto) to the west of the caldera. The youngest Whakamaru ignimbrite eruptions likely deposited to the northwest of the caldera contemporaneously with the Manunui ignimbrite to the west of the caldera. We calculate pre-eruptive storage temperatures (via zircon saturation geothermometry) and pressures (via rhyolite-MELTS geobarometry) using the glass compositions of the pumice clasts. We determine pressures of extraction from magma mush (via rhyolite-MELTS geobarometry) using matching whole-rock compositions. Melt-dominated magmas were stored at shallow depths (~50-150 MPa) prior to eruption. Types B and C extraction pressures are well constrained to 155-355 MPa. For types A and D, extraction pressures depend on the modeled oxygen fugacity (fO2), exhibiting a narrower range given a specific fO2 (overall range 170-360 MPa). Our results suggest there are at least two different magma subsystems that fed the Whakamaru eruptions – one subsystem sourced the type A and type D magmas, while the other sourced the type B and type C magmas. Both subsystems show gaps between storage and extraction pressures, suggesting separation between melt-dominated magma bodies and the magma mush bodies from which they were extracted. Combination of petrological data from the ignimbrites and associated tephras suggest a complex system that included laterally juxtaposed melt-dominated magmas as well as laterally juxtaposed magma mushes that spanned much of the shallow crust, but with regions in which magma appeared in low concentration or was entirely absent. Ignimbrite deposition across the landscape follows patterns revealed by the chronology observed in the tephra sequence.

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Section: Introductionmentioning

confidence: 99%

The Whakamaru Magmatic System (Taupō Volcanic Zone, New Zealand), Part 2: Evidence from ignimbrite deposits for pre-eruptive distribution of melt-dominated magma and magma mushes

Harmon,

Smithies,

Gualda

et al. 2024

Preprint

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“…The interaction (i.e., mingling/mixing) among different magma batches at Campi Flegrei was accompanied by other open-system processes such as crustal contamination and CO 2 flushing, as well as the removal of earlier grown crystals from their equilibrium melts. Another important finding of Pelullo et al [24] was the acknowledgment that using one single geothermobarometer does not constrain with certainty the magma storage conditions. Rather, a combination of various methods provides more reliable P-T estimates that, in the case of the Campi Flegrei complex volcanic system, are in agreement with independent estimates based on petrological and geophysical methods.…”

mentioning

confidence: 99%

“…Pelullo et al [24] combined various equilibrium tests and geothermobarometric methods, which they applied to a suite of Campi Flegrei volcanic rocks and related minerals spanning the activity period from ~59 ka to 1538 A.D. (for a review see [25] and references therein), constituting a large set of mineral and bulk-rock chemistry data from the literature. The aim was to evaluate the reliability of the various methodologies in inferring pre-eruptive magma storage conditions.…”

mentioning

confidence: 99%

Editorial for the Special Issue “Minerals of Alkaline Igneous Rocks: Chemical and Isotopic Features as Tracers of Magmatic Processes”

D’Antonio

Arienzo

2022

Minerals

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What can we learn from geothermobarometry at the dacitic Doña Juana Volcanic Complex (Colombia)? Implications for understanding Pleistocene crystal mushes and pre-eruptive storage conditions in the Northern Andes

Bucheli,

Pardo,

Larrea

et al. 2024

Contrib Mineral Petrol

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We present a reconstruction of the physicochemical conditions of melts in the Pleistocene storage and plumbing system of the Doña Juana Volcanic Complex (SW Colombia): a poorly known, potentially active polygenetic volcano of dacitic composition comprising four major edifices and showing periods of long quiescence. Compositional data for plagioclase, amphibole, pyroxene, and Fe-Ti oxides were combined with new and existing whole-rock data from representative eruptive products, allowing for the implementation of equilibrium tests and geothermobarometry calculations within an established stratigraphic, petrographic, and geochronological framework. Textural and geochemical variabilities of all mineral phases suggest the existence of a trans-crustal magmatic system feeding the Pleistocene eruptions of Doña Juana, and cyclic rejuvenation of a crystal mush following each volcano edifice collapse. The assemblage of different crystal cargos before magma recharge and final eruption is attested by (i) the coexistence of equilibrium and disequilibrium textures and variable compositions in crystals of all studied species, (ii) felsic cores in antecrysts, (iii) mafic overgrowth rims, and (iv) significantly less differentiated microcrysts relative to the composition of meso- and macrocrysts. By integrating multiple mineral-only and mineral-liquid geothermobarometers, after careful textural analyses, we estimate the intensive parameters of the mush–melt interaction zone of the plumbing system in the middle crust, providing a preliminary view of the architecture of a trans-crustal magmatic system in a complex tectonic setting at a previously understudied area of the north-Andean volcanic zone.

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Mineral-Melt Equilibria and Geothermobarometry of Campi Flegrei Magmas: Inferences for Magma Storage Conditions

Cited by 12 publications

References 160 publications

The Whakamaru Magmatic System (Taupō Volcanic Zone, New Zealand), Part 2: Evidence from ignimbrite deposits for pre-eruptive distribution of melt-dominated magma and magma mushes

The Whakamaru Magmatic System (Taupō Volcanic Zone, New Zealand), Part 2: Evidence from ignimbrite deposits for pre-eruptive distribution of melt-dominated magma and magma mushes

Editorial for the Special Issue “Minerals of Alkaline Igneous Rocks: Chemical and Isotopic Features as Tracers of Magmatic Processes”

What can we learn from geothermobarometry at the dacitic Doña Juana Volcanic Complex (Colombia)? Implications for understanding Pleistocene crystal mushes and pre-eruptive storage conditions in the Northern Andes

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