Source reservoir controls on the size, frequency, and composition of large-scale volcanic eruptions

Catherine Booth*, Matthew Jackson*, R S J Sparks, Alison C Rust

*Corresponding author for this work

Research output: Contribution to journalArticle (Academic Journal)peer-review

Abstract

Large-scale, explosive volcanic eruptions are one of the Earth’s most hazardous natural phenomena. We demon- strate that their size, frequency, and composition can be explained by processes in long-lived, high-crystallinity source reservoirs that control the episodic creation of large volumes of eruptible silicic magma and its delivery to the subvolcanic chamber where it is stored before eruption. Melt percolates upward through the reservoir and accumulates a large volume of low-crystallinity silicic magma which remains trapped until buoyancy causes magma-driven fractures to propagate into the overlying crust, allowing rapid magma transfer from the reservoir into the chamber. Ongoing melt percolation in the reservoir accumulates a new magma layer and the process repeats. Our results suggest that buoyancy, rather than crystallinity, is the key control on magma delivery from the source reservoir. They identify an optimum reservoir size for the largest silicic eruptions that is consistent with data from natural systems and explain why larger magnitude eruptions are not observed on Earth.
Original languageEnglish
Article numberadd1595
JournalScience Advances
Volume10
Issue number19
DOIs
Publication statusPublished - 10 May 2024

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