Publications

Marchese, F; Filizzola, C; Lacava, T; Falconieri, A; Faruolo, M; Genzano, N; Mazzeo, G; Pietrapertosa, C; Pergola, N; Tramutoli, V; Neri, M (2021). Mt. Etna Paroxysms of February-April 2021 Monitored and Quantified through a Multi-Platform Satellite Observing System. REMOTE SENSING, 13(16), 3074.

Abstract
On 16 February 2021, an eruptive paroxysm took place at Mt. Etna (Sicily, Italy), after continuous Strombolian activity recorded at summit craters, which intensified in December 2020. This was the first of 17 short, but violent, eruptive events occurring during February-April 2021, mostly at a time interval of about 2-3 days between each other. The paroxysms produced lava fountains (up to 1000 m high), huge tephra columns (up to 10-11 km above sea level), lava and pyroclastic flows, expanding 2-4 km towards East and South. The last event, which was characterised by about 3 days of almost continuous eruptive activity (30 March-1 April), generated the most lasting lava fountain (8-9 h). During some paroxysms, volcanic ash led to the temporary closure of the Vincenzo Bellini Catania International Airport. Heavy ash falls then affected the areas surrounding the volcano, in some cases reaching zones located hundreds of kilometres away from the eruptive vent. In this study, we investigate the Mt. Etna paroxysms mentioned above through a multi-platform satellite system. Results retrieved from Advanced Very High Resolution Radiometer (AVHRR), Moderate Resolution Imaging Spectroradiometer (MODIS), and Spinning Enhanced Visible and Infrared Imager (SEVIRI), starting from outputs of the Robust Satellite Techniques for Volcanoes (RSTVOLC), indicate that the 17th paroxysm (31 March-1 April) was the most powerful, with values of radiative power estimated around 14 GW. Moreover, by the analysis of SEVIRI data, we found that the 5th and 17th paroxysms were the most energetic. The Multispectral Instrument (MSI) and the Operational Land Imager (OLI), providing shortwave infrared (SWIR) data at 20/30 m spatial resolution, enabled an accurate localisation of active vents and the mapping of the areas inundated by lava flows. In addition, according to the Normalized Hotspot Indices (NHI) tool, the 1st and 3rd paroxysm (18 and 28 February) generated the largest thermal anomaly at Mt. Etna after June 2013, when Landsat-8 OLI data became available. Despite the impact of clouds/plumes, pixel saturation, and other factors (e.g., satellite viewing geometry) on thermal anomaly identification, the used multi-sensor approach allowed us to retrieve quantitative information about the 17 paroxysms occurring at Mt. Etna. This approach could support scientists in better interpreting changes in thermal activity, which could lead to future and more dangerous eruptions.

DOI:
10.3390/rs13163074

ISSN: