Abstract
Stromboli volcano has a persistent activity that is almost exclusively explosive. Predominated by low intensity events, this activity is occasionally interspersed with more powerful episodes, known as major explosions and paroxysms, which represent the main hazards for the inhabitants of the island. Here, we propose a machine learning approach to distinguish between paroxysms and major explosions by using satellite-derived measurements. We investigated the high energy explosive events occurring in the period January 2018–April 2021. Three distinguishing features are taken into account, namely (i) the temporal variations of surface temperature over the summit area, (ii) the magnitude of the explosive volcanic deposits emplaced during each explosion, and (iii) the height of the volcanic ash plume produced by the explosive events. We use optical satellite imagery to compute the land surface temperature (LST) and the ash plume height (PH). The magnitude of the explosive volcanic deposits (EVD) is estimated by using multi-temporal Synthetic Aperture Radar (SAR) intensity images. Once the input feature vectors were identified, we designed a k-means unsupervised classifier to group the explosive events at Stromboli volcano based on their similarities in two clusters: (1) paroxysms and (2) major explosions. The major explosions are identified by low/medium thermal content, i.e., LSTI around 1.4 °C, low plume height, i.e., PH around 420 m, and low production of explosive deposits, i.e., EVD around 2.5. The paroxysms are extreme events mainly characterized by medium/high thermal content, i.e., LSTI around 2.3 °C, medium/high plume height, i.e., PH around 3330 m, and high production of explosive deposits, i.e., EVD around 10.17. The centroids with coordinates (PH, EVD, LSTI) are: Cp (3330, 10.7, 2.3) for the paroxysms, and Cme (420, 2.5, 1.4) for the major explosions.
Highlights
Stromboli volcano is a small island in the southern TyrrhenianSea (Italy), which has been continuously erupting for the past 2000 years [1]
We have investigated the most powerful events occurring from January 2018 to April 2021 at Stromboli volcano by examining the land surface temperature (LST) time series derived by the daily Moderate Resolution Imaging
We focus on the surface temperature time series over the volcanic summit area, the pre- and post-eruptive Synthetic Aperture Radar (SAR) intensity images, and satellite optical images acquired during each event and its corresponding atmospheric profile
Summary
Stromboli volcano is a small island (less than 5 km wide) in the southern TyrrhenianSea (Italy), which has been continuously erupting for the past 2000 years [1]. Its activity is almost exclusively explosive, but lava flows do occur at times, most recently in 2014 and 2020 [2,3]. Its persistent but moderate explosive activity, termed “Strombolian”, is occasionally interrupted by explosive events that are more violent and represent the main hazard for the inhabitants of the island (less than 500 in winter, but more than 5000 in summer). The products of the most powerful explosive eruptions can damage the buildings [4]. Fatalities and injuries may occur, such as in the summer 2019 [6]. To assess the hazards faced by communities living on the island, it is fundamental to detect the explosions of different magnitude and intensity and understand how to classify them. The classification being a paramount issue for a correct hazard assessment [7], in the last decades several classifications have been
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