A chemical threshold controls nanocrystallization and degassing behaviour in basalt magmas

Scarani, Alex; Zandonà, Alessio; Fiore, Fabrizio Di; Valdivia, Pedro; Putra, Rizaldi; Miyajima, Nobuyoshi; Bornhöft, Hansjörg; Vona, Alessandro; Deubener, Joachim; Romano, Claudia; Genova, Danilo Di

doi:10.1038/s43247-022-00615-2

Cited by 25 publications

(37 citation statements)

References 199 publications

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“…and Tpeak; when such deviations were observed, Raman spectra were acquired to document that the sample changed during the measurement (i.e., crystallization and/or degassing). We indeed demonstrated in several recent works that Raman spectroscopy can reveal the precipitation of nanosized Fe-Ti-oxides (as expected during calorimetric measurements of magmatic melts at deep undercooling, where transition metals are poorly soluble and homogeneous crystal nucleation prevails over crystal growth), with sensitivity extending even to the early stages of amorphous phase separation anticipating the occurrence of actual crystals (Di Genova et al, 2020b, 2020a, 2017a, 2017bScarani et al, 2022;Zandona et al, 2022Zandona et al, , 2021Zandona et al, , 2019. Using this approach, we concluded that sample S38F5W1 may be reliably measured for qh ranging between 100 and 30000 K s -1 (see the expected linear dependence on qh in Figure 6); we obtained Tonset = 1055 ± 3 K and Tpeak = 1090 ± 1 K at qh = 1000 K s -1 .…”

Section: (Flash) Calorimetrysupporting

confidence: 69%

“…The experimental procedure applied in this work has been presented, tested and optimized in previous studies (Cassetta et al, 2021;Di Genova et al, 2020b;Scarani et al, 2022;Stabile et al, 2021); its cornerstones are briefly summarized here. We have demonstrated that the combination of calorimetry (DSC) and Brillouin spectroscopy (BLS) enables the modelling of melt viscosity as a function of temperature [η(T)] (Cassetta et al, 2021).…”

Section: Deriving and Modelling Melt Viscositymentioning

confidence: 99%

“…The melt fragility m was derived spectroscopically from BLS measurements performed on glasses at room temperature (Cassetta et al, 2021) because this approach avoids the need to acquire viscosity data over an extended temperature range, which is challenging or impossible for poor glass-forming liquids (Di Genova et al, 2020b;Kleest et al, 2020;Liebske et al, 2003b;Richet et al, 1996;Scarani et al, 2022). Fragility m was obtained as (Eq.…”

Section: Deriving and Modelling Melt Viscositymentioning

confidence: 99%

“…Using this approach, we concluded that sample S38F5W1 may be reliably measured for qh ranging between 100 and 30000 K s -1 (see the expected linear dependence on qh in Figure 6); we obtained Tonset = 1055 ± 3 K and Tpeak = 1090 ± 1 K at qh = 1000 K s -1 . For qh ≥ 5,000 K s -1 we limited the matching upscans to temperatures ≤ Tpeak, as the exposure of the melt to higher temperatures induced partial crystallization (Di Genova et al, 2020b;Scarani et al, 2022), inferred from the opacification of the glass and the appearance of the sharp characteristic features (e.g., at ~670 cm -1 ) of Fe-Ti-oxide crystals in its Raman spectrum (Di Genova et al, 2020a, 2020b, 2017b. Tonset values obtained at 1000 K min -1 from all hydrous peridotite glasses, plotted as a function of the water molar content: the higher the water content, the lower Tonset.…”

Section: (Flash) Calorimetrymentioning

confidence: 99%

“…Unfortunately, there are undeniable experimental challenges related to the viscosity measurements of volcanic melts (or their synthetic analogs), namely: (i) their undercooling-driven tendency to crystallize, which typically limits concentric-cylinder low-viscosity (~10 4 -10 -2 Pa s) determinations (e.g., Kolzenburg et al, 2018) to superliquidus temperatures and only mild undercooling; (ii) the prompt degassing of volatile-bearing melts at ambient pressure, which can be only overcome through falling-sphere experiments and the application of confining pressure (e.g., Liebske et al, 2005), with significant technical difficulties; (iii) the limited glass-forming ability of volcanic compositions, since glassy samples are necessary for high-viscosity (10 12 -10 6 Pa s) measurements by micropenetration (e.g., Di Genova et al, 2020b), parallel-plate deformation (e.g., Whittington et al, 2009), beam bending (e.g., Hagy, 1963) or fiber elongation (e.g., Taniguchi, 1992) viscometry. Moreover, even when the required glassy samples can be synthesized, their limited stability during high-temperature measurements has been repeatedly demonstrated by postmortem measurements using Raman spectroscopy and high-resolution imaging (Di Genova et al, 2020b, 2017aKleest et al, 2020;Liebske et al, 2003a;Scarani et al, 2022): nanocrystallization of Fe-Ti-oxides can affect sample homogeneity and alter the composition of the residual melt, preventing derivation of the crystal-free viscosity. As a consequence, currently available viscosity models (Giordano et al, 2008;Hui and Zhang, 2007;Langhammer et al, 2022) have been trained in a relatively restricted volcanological domain of temperature and chemistry, with questionable applicability to compositional extremes such as ultrabasic melts and very H2O-rich matrices.…”

Section: Introductionmentioning

confidence: 99%

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Viscosity of anhydrous and hydrous peridotite melts

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Section: (Flash) Calorimetrysupporting

confidence: 69%

Section: Deriving and Modelling Melt Viscositymentioning

confidence: 99%

Section: Deriving and Modelling Melt Viscositymentioning

confidence: 99%

Section: (Flash) Calorimetrymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Viscosity of anhydrous and hydrous peridotite melts

et al. 2023

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Are volcanic melts less viscous than we thought? The case of Stromboli basalt

Valdivia

Zandonà

Kurnosov

et al. 2023

Contrib Mineral Petrol

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Melt viscosity is one of the most critical physical properties controlling magma transport dynamics and eruptive style. Although viscosity measurements are widely used to study and model the flow behavior of magmas, recent research has revealed that nanocrystallization of Fe–Ti-oxides can compromise the reliability of viscosity data. This phenomenon can occur during laboratory measurements around the glass transition temperature (Tg) and lead to the depletion of iron and titanium in the residual melt phase, with a significant increase in viscosity. Accurate viscosity measurements play a crucial role in determining the reliability of empirical models for magma viscosity, which are used to evaluate eruptive scenarios in hazardous areas. Here, we quantify the reliability of empirical models by elaborating a new viscosity model of Stromboli basalt that relies exclusively on viscosity data obtained from nanocrystal-free samples. We show that empirical models so far used to estimate melt viscosity at eruptive conditions overestimate Stromboli viscosity by a factor ranging between 2 and 5. In the context of numerical modelling of magmatic processes at Stromboli volcano, we analyse and interpret this finding. Based on our findings, we draw the conclusion that Stromboli basalt is anticipated to ascend from the storage area to the vent at a faster rate than previously hypothesized.

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Generation of deposit-derived pyroclastic density currents by repeated crater rim failures at Stromboli Volcano (Italy)

Di Traglia,

Berardino,

Borselli

et al. 2024

Bull Volcanol

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The gravitational instability of hot material deposited during eruptive activity can lead to the formation of glowing avalanches, commonly known as deposit-derived pyroclastic density currents (PDCs). These currents can travel hundreds of metres to several kilometres from the source at exceptionally high temperatures, posing a catastrophic hazard to areas surrounding steep-slope volcanoes. The occurrence of deposit-derived PDCs is often associated with crater rim failure, which can be triggered by various factors such as magma thrust from dike injection, magma fingering, bulging or less commonly, powerful explosions. Here, the in-depth study of data from the multi-parametric monitoring network operating on Stromboli (Italy), including video surveillance, seismicity and ground deformation data, complemented by remote topographic sensing data, has facilitated the understanding of the events leading to the crater rim collapse on 9 October and 4 December 2022. The failures resulted in the remobilisation of 6.4 ± 1.0 × 103 m3 and 88.9 ± 26.7 × 103 m3 of material for the 9 October and the 4 December 2022, respectively, which propagated as PDCs along the NW side of the volcano and reached the sea in a few tens of seconds. These events were characterised by a preparatory phase marked by an increase in magmatic pressure in the preceding weeks, which correlated with an increase in the displacement rate of the volcano’s summit. There was also an escalation in explosive degassing, evidenced by spattering accompanied by seismic tremors in the hours before the collapse.These events have been interpreted as an initial increase in magma vesicularity, followed by the release of gas once percolation threshold was reached. The degassing process induced densification of the magma, resulting in increased thrust on the conduit walls due to increased magmastatic pressure. This phase coincided with crater rim collapse, often followed or accompanied by the onset of lava overflow phases. A mechanism similar to the one proposed may shed light on similar phenomena observed at other volcanoes. The analysis performed in this study highlights the need for a multi-parametric and multi-platform approach to fully understand such complex phenomena. By integrating different data sources, including seismic, deformation and remote sensing data, it is possible to identify the phenomena associated with the different phases leading to crater rim collapse and the subsequent development of deposit-derived PDCs.

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A chemical threshold controls nanocrystallization and degassing behaviour in basalt magmas

Cited by 25 publications

References 199 publications

Viscosity of anhydrous and hydrous peridotite melts

Viscosity of anhydrous and hydrous peridotite melts

Are volcanic melts less viscous than we thought? The case of Stromboli basalt

Generation of deposit-derived pyroclastic density currents by repeated crater rim failures at Stromboli Volcano (Italy)

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