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Magma fragmentation in highly explosive basaltic eruptions induced by rapid crystallisation

Arzilli, F.; La Spina, G.; Burton, M.; Polacci, M.; Le Gall, N.; Hartley, M.; Di Genova, D.; Cai, B.; Vo, N.; Bamber, E.; Nonni, S.; Atwood, R.; Llewellin, E.; Brooker, R.; Mader, H.; Lee, P.

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Authors

F. Arzilli

G. La Spina

M. Burton

M. Polacci

N. Le Gall

M. Hartley

D. Di Genova

B. Cai

N. Vo

E. Bamber

S. Nonni

R. Atwood

R. Brooker

H. Mader

P. Lee



Abstract

Basaltic eruptions are the most common form of volcanism on Earth and planetary bodies. The low viscosity of basaltic magmas inhibits fragmentation, which favours effusive and lava-fountaining activity, yet highly explosive, hazardous basaltic eruptions occur. The processes that promote fragmentation of basaltic magma remain unclear and are subject to debate. Here we used a numerical conduit model to show that a rapid magma ascent during explosive eruptions produces a large undercooling. In situ experiments revealed that undercooling drives exceptionally rapid (in minutes) crystallization, which induces a step change in viscosity that triggers magma fragmentation. The experimentally produced textures are consistent with basaltic Plinian eruption products. We applied a numerical model to investigate basaltic magma fragmentation over a wide parameter space and found that all basaltic volcanoes have the potential to produce highly explosive eruptions. The critical requirements are initial magma temperatures lower than 1,100 °C to reach a syn-eruptive crystal content of over 30 vol%, and thus a magma viscosity around 105 Pa s, which our results suggest is the minimum viscosity required for the fragmentation of fast ascending basaltic magmas. These temperature, crystal content and viscosity requirements reveal how typically effusive basaltic volcanoes can produce unexpected highly explosive and hazardous eruptions.

Citation

Arzilli, F., La Spina, G., Burton, M., Polacci, M., Le Gall, N., Hartley, M., …Lee, P. (2019). Magma fragmentation in highly explosive basaltic eruptions induced by rapid crystallisation. Nature Geoscience, 12, 1023-1028. https://doi.org/10.1038/s41561-019-0468-6

Journal Article Type Article
Acceptance Date Sep 11, 2019
Online Publication Date Oct 21, 2019
Publication Date 2019
Deposit Date Oct 1, 2019
Publicly Available Date Apr 21, 2020
Journal Nature Geoscience
Print ISSN 1752-0894
Electronic ISSN 1752-0908
Publisher Nature Research
Peer Reviewed Peer Reviewed
Volume 12
Pages 1023-1028
DOI https://doi.org/10.1038/s41561-019-0468-6
Public URL https://durham-repository.worktribe.com/output/1290227

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