posted on 2023-05-18, 18:00authored byCassidy, M, Watt, SFL, Talling, PJ, Palmer, MR, Edmonds, M, Martin JutzelerMartin Jutzeler, Wall-Palmer, D, Manga, M, Coussens, M, Gernon, T, Taylor, RN, Michalik, A, Inglis, E, Breitkreuz, C, Le Friant, A, Ishizuka, O, Boudon, G, McCanta, MC, Adachi, T, Hornbach, MJ, Colas, SL, Endo, D, Fujinawa, A, Kataoka, KS, Maeno, F, Tamura, Y, Wang, F
Volcanic edifice collapses generate some of Earth's largest landslides. How such unloading affects the magma storage systems is important for both hazard assessment and for determining long-term controls on volcano growth and decay. Here we present a detailed stratigraphic and petrological analyses of volcanic landslide and eruption deposits offshore Montserrat, in a subduction zone setting, sampled during Integrated Ocean Drilling Program Expedition 340. A large (6–10 km3) collapse of the Soufrière Hills Volcano at ~130 ka was followed by explosive basaltic volcanism and the formation of a new basaltic volcanic center, the South Soufrière Hills, estimated to have initiated <100 years after collapse. This basaltic volcanism was a sharp departure from the andesitic volcanism that characterized Soufrière Hills' activity before the collapse. Mineral-melt thermobarometry demonstrates that the basaltic magma's transit through the crust was rapid and from midcrustal depths. We suggest that this rapid ascent was promoted by unloading following collapse.
History
Publication title
Geophysical Research Letters
Volume
42
Issue
12
Pagination
4778-4785
ISSN
0094-8276
Department/School
School of Natural Sciences
Publisher
Amer Geophysical Union
Place of publication
2000 Florida Ave Nw, Washington, USA, Dc, 20009
Rights statement
Copyright 2015 The Authors Licensed under Creative Commons Attribution 4.0 International (CC BY 4.0) http://creativecommons.org/licenses/by/4.0/