Moussallam Yves, Rose-Koga E. F., Koga K. T., Medard E., Bani Philipson, Devidal J. L., Tari D. (2019). Fast ascent rate during the 2017-2018 Plinian eruption of Ambae (Aoba) volcano : a petrological investigation. Contributions to Mineralogy and Petrology, 174 (11), p. art. 90 [24p.]. ISSN 0010-7999.
Titre du document
Fast ascent rate during the 2017-2018 Plinian eruption of Ambae (Aoba) volcano : a petrological investigation
Année de publication
2019
Auteurs
Moussallam Yves, Rose-Koga E. F., Koga K. T., Medard E., Bani Philipson, Devidal J. L., Tari D.
Source
Contributions to Mineralogy and Petrology, 2019,
174 (11), p. art. 90 [24p.] ISSN 0010-7999
In September 2017, after more than a hundred years of quiescence, Ambae (Aoba), Vanuatu's largest volcano, entered a new phase of eruptive activity, triggering the evacuation of the island's 11,000 inhabitants resulting in the largest volcanic disaster in the country's history. Three subsequent eruptive phases in November 2017, March 2018, and July 2018 expelled some of the largest tropospheric and stratospheric SO2 clouds observed in the last decade. Here, we investigate the mechanisms and dynamics of this eruption. We use major elements, trace elements, and volatiles in olivine and clinopyroxene hosted melt inclusions, embayments, crystals, and matrix glasses together with clinopyroxene geobarometry and olivine, plagioclase, and clinopyroxene geothermometry to reconstruct the physical and chemical evolution of the magma, as it ascends to the surface. Volatile elements in melt inclusions and geobarometry data suggest that the magma originated from depth of 14 km before residing at shallow ( 0.5 to 3 km) levels. Magma ascent to the surface was likely facilitated by shallow phreatic eruptions that opened a pathway for magma to ascend. Succeeding eruptive phases are characterised by increasingly primitive compositions with evidence of small amounts of mixing having taken place. Mg-Fe exchange diffusion modelling yields olivine residence times in the magma chamber ranging from a few days to a year prior to eruption. Diffusion modelling of volatiles along embayments (melt channels) from the first two phases of activity and microlite number density suggests rapid magma ascent in the range of 15-270 km/h, 4-75 m/s (decompression rates of 0.1 to 2 MPa/s) corresponding to a short travel time between the top of the shallow reservoir and the surface of less than 2 min.
Plan de classement
Géologie et formations superficielles [064]
;
Géophysique interne [066]
Description Géographique
VANUATU ; AMBAE VOLCAN
Localisation
Fonds IRD [F B010077140]
Identifiant IRD
fdi:010077140
