P. Allard scite author profile

Strombolian-type eruptive activity, common at many volcanoes, consists of regular explosions driven by the bursting of gas slugs that rise faster than surrounding magma. Explosion quakes associated with this activity are usually localized at shallow depth; however, where and how slugs actually form remain poorly constrained. We used spectroscopic measurements performed during both quiescent degassing and explosions on Stromboli volcano (Italy) to demonstrate that gas slugs originate from as deep as the volcano-crust interface (approximately 3 kilometers), where both structural discontinuities and differential bubble-rise speed can promote slug coalescence. The observed decoupling between deep slug genesis and shallow (approximately 250-meter) explosion quakes may be a common feature of strombolian activity, determined by the geometry of plumbing systems.

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Melt inclusion record of the conditions of ascent, degassing, and extrusion of volatile‐rich alkali basalt during the powerful 2002 flank eruption of Mount Etna (Italy)

Spilliaert

et al. 2006

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raising the possibility of changing magmatic conditions. Here we decipher the origin and mechanisms of the second eruption from the composition and volatile (H 2 O, CO 2 , S, Cl) content of olivine-hosted melt inclusions in explosive products from its south flank vents. Our results demonstrate that powerful lava fountains and ash columns at the eruption onset were sustained by closed system ascent of a batch of primitive, volatile-rich (!4 wt %) basaltic magma that rose from !10 km depth below sea level (bsl) and suddenly extruded through 2001 fractures maintained opened by eastward flank spreading. This magma, the most primitive for 240 years, probably represents the alkali-rich parental end-member responsible for Etna lavas' evolution since the early 1970s. Few of it was directly extruded at the eruption onset, but its input likely pressurized the shallow plumbing system several weeks before the eruption. This latter was subsequently fed by the extrusion and degassing of larger amounts of the same, but slightly more evolved, magma that were ponding at 6-4 km bsl, in agreement with seismic data and with the lack of preeruptive SO 2 accumulation above the initial depth of sulphur exsolution ($3 km bsl). We find that while ponding, this magma was flushed and dehydrated by a CO 2 -rich gas phase of deeper derivation, a process that may commonly affect the plumbing system of Etna and other alkali basaltic volcanoes.

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Eruptive and diffuse emissions of CO2 from Mount Etna

Allard

Carbonnelle

Dajlevic

et al. 1991

Nature

462

261

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2001 flank eruption of the alkali- and volatile-rich primitive basalt responsible for Mount Etna's evolution in the last three decades

Métrich

Allard

Spilliaert

et al. 2004

Earth and Planetary Science Letters

219

233

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Sulphur output and magma degassing budget of Stromboli volcano

Allard

Carbonnelle

Métrich

et al. 1994

Nature

318

230

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Spectroscopic evidence for a lava fountain driven by previously accumulated magmatic gas

Allard

Burton

Murè

2005

Nature

238

219

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Lava fountains are spectacular continuous gas jets, propelling lava fragments to heights of several hundred metres, which occasionally occur during eruptions of low-viscosity magmas. Whether they are generated by the effervescent disruption of fast-rising bubbly melt or by the separate ascent of a bubble foam layer accumulated at depth still remains a matter of debate. No field measurement has yet allowed firm discrimination between these two models. A key insight into the origin of lava fountains may be gained by measuring the chemical composition of the driving gas phase. This composition should differ markedly depending on whether the magma degassing occurs before or during eruption. Here we report the analysis of magmatic gas during a powerful (250-600 m high) lava fountain, measured with Fourier transform infrared spectroscopy on Mount Etna, Sicily. The abundances of volcanic gas species, determined from absorption spectra of lava radiation, reveal a fountain gas having higher CO2/S and S/Cl ratios than other etnean emissions, and which cannot derive from syn-eruptive bulk degassing of Etna basalt. Instead, its composition suggests violent emptying of a gas bubble layer previously accumulated at about 1.5 km depth below the erupting crater.

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Mount Etna 1993–2005: Anatomy of an evolving eruptive cycle

Allard

Behncke

D’Amico

et al. 2006

Earth-Science Reviews

234

228

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Endogenous magma degassing and storage at Mount Etna

Allard¹

1997

Geophysical Research Letters

200

160

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P. Allard

Magmatic Gas Composition Reveals the Source Depth of Slug-Driven Strombolian Explosive Activity

Melt inclusion record of the conditions of ascent, degassing, and extrusion of volatile‐rich alkali basalt during the powerful 2002 flank eruption of Mount Etna (Italy)

Eruptive and diffuse emissions of CO2 from Mount Etna

2001 flank eruption of the alkali- and volatile-rich primitive basalt responsible for Mount Etna's evolution in the last three decades

Sulphur output and magma degassing budget of Stromboli volcano

Spectroscopic evidence for a lava fountain driven by previously accumulated magmatic gas

Mount Etna 1993–2005: Anatomy of an evolving eruptive cycle

Endogenous magma degassing and storage at Mount Etna

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