2022
DOI: 10.1002/9781119722748.ch6
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Structure of the Shallow Supply System at Stromboli Volcano, Italy, through Integration of Muography, Digital Elevation Models, Seismicity, and Ground Deformation Data

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Cited by 8 publications
(9 citation statements)
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“…The drone survey carried out in September 2021, when compared to the previous profile obtained in June 2020 by Civico et al (2021), shows several zones of growth and accumulation of erupted products around most of the summit vents (Figure 5F), involving an increased hazard of further failures. In addition, a recent survey detected a significant volume increase of the talus building up the NE flank of the summit cone (Tioukov et al, 2022), thus confirming the summit area of the volcano as being prone to further collapses.…”
Section: Hazard Assessmentmentioning
confidence: 86%
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“…The drone survey carried out in September 2021, when compared to the previous profile obtained in June 2020 by Civico et al (2021), shows several zones of growth and accumulation of erupted products around most of the summit vents (Figure 5F), involving an increased hazard of further failures. In addition, a recent survey detected a significant volume increase of the talus building up the NE flank of the summit cone (Tioukov et al, 2022), thus confirming the summit area of the volcano as being prone to further collapses.…”
Section: Hazard Assessmentmentioning
confidence: 86%
“…Since the end of the 2007 flank eruption (Patané et al, 2007;Neri and Lanzafame 2009), the summit crater terrace depression grew mainly on its NE margin building up a thick talus by accumulation of debris, spatter and ejecta erupted during the persistent explosive activity by the NEC vents (Harris and Ripepe, 2007;Di Traglia et al, 2020;Schmid et al, 2021;Tioukov et al, 2022). This rapidly grown constructional morphology is also frequently affected by small collapses (~10 4 -10 5 m 3 ; Falsaperla et al, 2006;Civico et al, 2021).…”
Section: Introductionmentioning
confidence: 99%
“…Stromboli is a volcanic island in the Mediterranean Sea characterized by a persistent explosive activity that produces hundreds of moderate explosions per day. Three main vent regions are located in the upper part of the volcano: the North East (NE), the Central (C), and the South West (SW) vent regions (Figure 1) [18][19][20][21][22]. In recent decades, geophysical and volcanological studies have indicated that the ordinary explosive activity of Stromboli shows a variety of eruptive mechanisms and products, whose signature is distinguishable in the geophysical signals generated by the explosions (e.g., seismic and infrasonic signals).…”
Section: Introductionmentioning
confidence: 99%
“…The constant flux and the high penetration power of muons allow passive and remote imaging of the shallow density structures in volcanoes at a spatial resolution of few meters (Macedonio et al., 2022; Miyamoto et al., 2022; Nishiyama et al., 2014; Oláh et al., 2018). Muography has already been used to image the spatio‐temporal evolution of magmatic materials—for example, ascent and descent of magma within a volcanic vent (Tanaka et al., 2014), magma degassing (Tanaka et al., 2009), and plug formation underneath deactivated craters (Oláh et al., 2019)—and to observe structural changes (Lo Presti et al., 2022; Tioukov et al., 2022) and hydrothermal activities (Gibert et al., 2022) in volcanic systems. The early warning capabilities of muography have also been studied (Leone et al., 2021; Nomura et al., 2020; Oláh & Tanaka, 2022a).…”
Section: Methodsmentioning
confidence: 99%