Frontiers in Earth Science | 卷:6 |
Tephra From the 3 March 2015 Sustained Column Related to Explosive Lava Fountain Activity at Volcán Villarrica (Chile) | |
Jorge E. Romero1  Mohammad Ayaz Alam1  Alicia Guevara2  José L. Palma3  Franco Vera3  Jeffrey B. Johnson4  Daniele Morgavi5  Jorge E. Bustillos6  Evelyn Cuenca6  Werner Keller7  Fabio Arzilli8  Mike Burton8  Margherita Polacci8  | |
[1] Departamento de Geología, Facultad de Ingeniería, Universidad de Atacama, Copiapó, Chile; | |
[2] Departamento de Metalurgia Extractiva, Escuela Politécnica Nacional, Quito, Ecuador; | |
[3] Department of Earth Science, Faculty of Chemical Science, University of Concepción, Concepción, Chile; | |
[4] Department of Geosciences, Boise State University, Boise, ID, United States; | |
[5] Department of Physics and Geology, University of Perugia, Perugia, Italy; | |
[6] Escuela de Geología, Universidad Central de Ecuador, Quito, Ecuador; | |
[7] Proyecto de Observación Volcán Villarrica (POVI), Fundación Volcanes de Chile, Santiago, Chile; | |
[8] School of Earth and Environmental Sciences, University of Manchester, Manchester, United Kingdom; | |
关键词: lava fountain; tephra fall; eruption parameters; Villarrica Volcano; Southern Andes; | |
DOI : 10.3389/feart.2018.00098 | |
来源: DOAJ |
【 摘 要 】
Exceptionally intense lava fountains at open conduit volcanoes are infrequent, hazardous and little-warned events. Studying their tephra falls may reveal conduit dynamics, eruption source parameters and fragmentation mechanisms. Villarrica Volcano (Southern Andes of Chile) has sustained persistent open conduit activity, associated with a dynamic lava lake since at least 1984–85. Increased seismicity and degassing in August 2014 were followed by Strombolian activity starting in February 2015 and culminated with a 1.5 km-high lava fountain on 3 March 2015. This eruption produced tephra fallout, spatter agglutination, clastogenic lavas and mixed avalanche deposits. Here we characterized for first time Villarrica's 3 March 2015 tephra fall deposits produced by lava fountain and its rapid transition to sustained eruption column, providing valuable information on paroxysmal activity in open conduit volcanoes. Tephra was dispersed southeast of the crater in a narrow, elongated, nearly-elliptic area. Minimum observed tephra loading was estimated to be 80–120 g/m2 at crosswind locations, while maximum load estimation was about 11,500 g/m2, at 7–9 km distance from the vent. At 6–8 km downwind, the tephra fall deposit consisted of a single black scoria layer; fall varied from a lapilli blanket at medial distances (9–19 km) to a few individual particles at distal sites (20–43 km). All samples are vitrophyric and contain plagioclase (3–30%), clinopyroxene (2–5%), olivine (1–4%) and orthopyroxene (<1%) phenocrysts. We estimate that 1.4 × 109 kg, equivalent to ~2.4 × 106 m3 of basaltic andesite tephra (52.7–54.7 SiO2 wt. %), were erupted within a period of about 16 min at a mass eruption rate of ~1.5 × 106 kg/s. The sustained eruption column height was estimated at ~10.8 km, with magnitude and intensity of 2.11 and 9.13 respectively. We propose that a rejuvenated, volatile-rich magmatic intrusion probably triggered paroxysmal activity. The Villarrica eruption is classified as a short-lived, large-scale lava fountain, similar to analogous historical events at Mt. Etna and Kilauea. As evident by devastating twentieth century Villarrica eruptions which also developed similar lava fountains, this eruption style should be considered as frequent and a potential source of volcanic hazard in the future.
【 授权许可】
Unknown