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Systematic SO2 emission patterns prior, during, and after Mt. Etna’s paroxysmal phases captured by ultraviolet cameras (2024)

Delle Donne, Dario ; Aiuppa, Alessandro ; Bitetto, Marcello ; [et al.]

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Publication Date: 2024-01-26

Description: We used two and a half years long SO2 flux record, obtained using permanent ultraviolet cameras, to characterize changes in degassing dynamics at Mt. Etna volcano from summer 2014 to the end of 2016. Volcanic activity at Mt. Etna was characterized by persistent open-vent degassing periodically interrupted by intense paroxysmal lava fountaining events (in August 2014, December 2015, and May 2016). Results revealed systematic SO2 emission patterns prior, during, and after Etna’s paroxysmal phases, allowing us to identify thresholds between pre-syn-and post-eruptive degassing regimes. The SO2 flux typically peaked during a lava fountain: in the 18 May 2016 example, the averaged SO2 degassing rate was ~158 kg/s, the peak emission was ~260 kg/s, and the total released SO2 mass was ~1700 tons (in 3h). Paroxysmal explosive activity at NSE crater on 11-15 August 2014 was also associated with intense syneruptive SO2 degassing (at 30-40 kg/s levels on a daily average), and was preceded by onset in degassing activity at the same crater 4 days before. During paroxysmal activity on 3-5 December 2015, the SO2 fluxes peaked at 54-103 kg/s from VOR crater, and was preceded by a sizable increase from 10 kg/s (end of November) up to 45.5 kg/s, two days before. The May 16-25 2016 paroxysmal activity was characterized by intense degassing ~2 times higher than the 2016 average (~18 kg/s) and preceded by mild but detectable SO2 flux increases more than one month before its onset. Taken together, our observations, when combined with independent geophysical (thermal and seismic) evidence, allow us to fully characterize the Etna’s degassing dynamics and contribute to our understanding of its shallow plumbing system.

Description: Published

Description: Catania

Description: OSV2: Complessità dei processi vulcanici: approcci multidisciplinari e multiparametrici

Keywords: SO2 ; Mt. Etna volcano ; permanent ultraviolet cameras

Repository Name: Istituto Nazionale di Geofisica e Vulcanologia (INGV)

Type: Abstract

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A SO2 flux study of the Etna volcano 2020–2021 paroxysmal sequences (2024)

Aiuppa, Alessandro ; Lo Bue Trisciuzzi, Giovanni ; Alparone, Salvatore ; [et al.]

Frontiers S.A.

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Publication Date: 2024-01-25

Description: The persistent open-vent degassing of Mt. Etna is often punctuated by monthslong paroxysmal sequences characterized by episodes of violent Strombolian to lava fountaining activity. Understanding these gas-fueled transitions from quiescence to eruption requires routine measurement of gas fluxes. Here, we report SO2 flux measurements, obtained from a permanent UV camera system, collected over a two-year-long period spanning two paroxysmal sequences of Etna’s New South East Crater (NSEC) in December 2020/April 2021 and May/ October 2021. In both cases, SO2 flux increased from ≤ 3250 Mg/day during “ordinary” activity to ≥ 4200 Mg/day. We interpret these distinct SO2 degassing regimes in light of seismic and thermal observations and drawing on numerical simulations of sulfur degassing constrained by parental melt sulfur contents in Etna’s hawaiites. We find that initiation of a paroxysmal sequence results from an approximate doubling of the time-averaged rate of magma supply (and degassing) above the sulfur exsolution level (~150 MPa pressure), to 〉4m3/s. This corroborates recent models that argue for the triggering of paroxysmal sequences by escalating supply of volatile-rich magma to a reservoir ~3–4 km below the summit region. The non-stationary nature of magma flow and volcanic degassing we identify highlights the need for sustained surveillance to characterize long-term atmospheric budgets of volcanic volatiles

Description: Published

Description: 1115111