The Long-Term Life-Cycle of Nevado de Toluca Volcano (Mexico): Insights Into the Origin of Petrologic Modes

Weber, Gregor; Caricchi, Luca; Arce, José Luis

doi:10.3389/feart.2020.563303

Cited by 7 publications

(3 citation statements)

References 138 publications

(220 reference statements)

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“…3 a, caldera systems producing diverse magma chemistry like Mazama, Santorini, or Los Humeros have lifespans equivalent or shorter than many examples of long-lived stratovolcanoes (e. g., Uturuncu, Aucanquilcha, Xinantécatl) that have produced monotonous andesitic-dacitic magma chemistry throughout their > 1.5 Ma histories 41 – 43 . In order to maintain their monotonous character over such long timescales, pre-eruptive magma storage depth and temperatures for such volcanoes must be relatively constant and balanced by eruption rates 44 . For younger, more monotonous basaltic systems (e.g., Tolbachik, Merapi; Fig.…”

Section: Discussionmentioning

confidence: 99%

Geochemical variability as an indicator for large magnitude eruptions in volcanic arcs

Weber

Sheldrake

2022

Sci Rep

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Caldera-forming eruptions have the potential to induce drastic socioeconomic change. However, the criteria to identify volcanoes capable of producing large magnitude eruptions in the future are not well constrained. Here we compile and analyse data, revealing that volcanoes which have produced catastrophic caldera-forming eruptions in the past, show larger ranges of erupted magma geochemistry compared to those that have not. This suggests geochemical variability is related to the size of magmatic systems. Using heat transfer simulations, we show that differences in magma flux result in a dependency between chemical diversity and magma volume that is consistent with these observations. We conclude that compositional spread should be included in the catalogue of criteria to identify volcanoes with greater probability of producing future large eruptions. Importantly, this allows to identify stratovolcanoes with caldera-like geochemical signatures, which have not yet been recognized as systems with greater likelihood of producing large magnitude eruptions.

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Section: Discussionmentioning

confidence: 99%

Geochemical variability as an indicator for large magnitude eruptions in volcanic arcs

Weber

Sheldrake

2022

Sci Rep

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“…The P-T-X of magma during storage and ascent plays a leading role in modulating eruptive dynamics (Higgins and Caricchi, 2023;Popa et al, 2021). Therefore, quantitative tools to describe pre-eruptive magmatic P-T-X, such as the new thermobarometric equations presented here, can be useful to: (i) petrologically monitor active volcanoes during protracted eruptions, particularly to compare evolving geochemical and geophysical signals Longpré et al, 2014;Magee et al, 2018Magee et al, , 2020Saunders et al, 2012;Stock et al, 2018); (ii) understand medium-term and long-term evolution in magma storage conditions by studying multiple temporally constrained volcanic deposits (Bouvet de Maisonneuve et al, 2021;Forni et al, 2018;Giordano and Caricchi, 2022;Higgins et al, 2021a;Smithies et al, 2023;Weber et al, 2020). To assess the utility of our new thermobarometer for studying volcanic systems, we apply our calibration to the OPAMSAT melts of two case study eruptions 5.…”

Section: Application To Two Geophysically Monitored Volcanic Eruptionsmentioning

confidence: 99%

“…Irrespective of the calibration strategy, thermobarometers have significant scope as petrological volcano monitoring tools. For example, P data can independently validate geophysical estimates of pre-eruptive magma storage depth during or after eruptions (Hartley et al, 2018;Stock et al, 2018;Ubide et al, 2023) or catalogue past changes in magma P and T for eruptions of volcanoes that lack a protracted historical monitoring record (Bouvet de Maisonneuve et al, 2021;Higgins et al, 2021a;Jorgenson et al, 2024;Weber et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

A new calibration of the OPAM thermobarometer for anhydrous and hydrous mafic systems

Higgins,

Stock

2024

Preprint

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Melt-based thermobarometers are essential tools to recover pre-eruptive magma storage conditions through their application to bulk rock and liquid chemistry. In active volcanic systems, thermobarometric results can be combined with independent geophysical data during or after an eruption to validate conceptual models. In this contribution, we revisit the thermobarometer for melts equilibrated with the mineral assemblage of olivine + plagioclase + augitic clinopyroxene (OPAM). We first demonstrate that the most widely applied OPAM thermobarometer suffers from both random and systematic uncertainty even for anhydrous melts, and that the uncertainty increases proportionally with melt H2O. To address this issue, we use a modern compilation of anhydrous and hydrous OPAM-saturated experiments to regress a new melt-based OPAM thermometer and barometer. Our new equations recover a validation dataset with a standard error estimate (SEE) of ±1.1 kbar and ±35 ˚C for pressure and temperature respectively, as well as a low systematic uncertainty that does not depend on melt H2O. Additionally, we present a novel statistical approach to determine the probability that a given melt is OPAM-saturated, which can be used alongside petrographic observations. Our thermobarometer and saturation test are presented as a straightforward R script which reads from an input csv file to be populated with natural data. We benchmark the new calibrations on the products of the 2015 eruption of Wolf Volcano (Isabela Island, Galápagos) and the 2014-2015 Holuhraun eruption (Iceland), both of which have independent geophysical estimates of magma storage that agree well with our thermobarometric results.

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A micro-scale insight into a back-arc trans-crustal plumbing system: The case of Marsili volcano, Southern Tyrrhenian Sea

Colle,

Masotta,

Costa

et al. 2024

Lithos

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The Long-Term Life-Cycle of Nevado de Toluca Volcano (Mexico): Insights Into the Origin of Petrologic Modes

Cited by 7 publications

References 138 publications

Geochemical variability as an indicator for large magnitude eruptions in volcanic arcs

Geochemical variability as an indicator for large magnitude eruptions in volcanic arcs

A new calibration of the OPAM thermobarometer for anhydrous and hydrous mafic systems

A micro-scale insight into a back-arc trans-crustal plumbing system: The case of Marsili volcano, Southern Tyrrhenian Sea

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