Magma degassing and fragmentation during the 1918 Katla eruption

The last eruption of the restless, ice-covered Katla volcanic system in south Iceland was a 1 km3 (DRE) explosive subglacial basaltic event in 1918, which released a 8 km3 meltwater flood. We have sampled both the 1918 jökulhlaup deposit and airfall tephra preserved on Sólheimajökull. Sampling of mu...

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Bibliographic Details
Main Authors: Owen, Jacqueline, Tuffen, Hugh, Coats, Becky
Format: Conference Object
Language:unknown
Published: 2015
Subjects:
Katla
Sólheimajökull
Iceland
Online Access:https://eprints.lancs.ac.uk/id/eprint/74467/
id ftulancaster:oai:eprints.lancs.ac.uk:74467
record_format openpolar
spelling ftulancaster:oai:eprints.lancs.ac.uk:74467 2023-08-27T04:10:12+02:00 Magma degassing and fragmentation during the 1918 Katla eruption Owen, Jacqueline Tuffen, Hugh Coats, Becky 2015 https://eprints.lancs.ac.uk/id/eprint/74467/ unknown Owen, Jacqueline and Tuffen, Hugh and Coats, Becky (2015) Magma degassing and fragmentation during the 1918 Katla eruption. In: IUGG, 2015-06-222015-07-02. Contribution to Conference NonPeerReviewed 2015 ftulancaster 2023-08-03T22:27:45Z The last eruption of the restless, ice-covered Katla volcanic system in south Iceland was a 1 km3 (DRE) explosive subglacial basaltic event in 1918, which released a 8 km3 meltwater flood. We have sampled both the 1918 jökulhlaup deposit and airfall tephra preserved on Sólheimajökull. Sampling of multiple layers allows examination of discrete phases of eruption/emplacement. Tephra was sieved and clasts thin sectioned to analyse bubble textures, and for compositional analysis using electron probe microanalysis (EPMA) and laser ablation inductively coupled mass spectrometry (LA-ICP-MS). Part of the clasts were analysed for volatile contents using fourier transform infrared spectroscopy (FTIR) and thermogravimetric analysis (TGA). Jökulhlaup samples show evidence of interaction with water; the glass is microlite-poor with ~0.2-0.3 wt.% H2O consistent with quenching under elevated pressure. Some air-fall clasts are microlite rich, completely degassed (~0.1 wt.% H2O) and have interior bubbles that are significantly larger than those at the clast margin. We interpret this as post-fragmentation degassing. These clasts should have taken seconds to cool had they quenched in water. Hot-stage experiments show average bubble growth rates of ~1 µm s-1, suggesting that such clasts have had very little/no interaction with water. Many clasts show repeated episodes of fragmentation and/or degassing, suggesting recycling of material in the upper conduit and/or vent. Preliminary LA-ICP-MS data hints that the magma chamber may have been compositionally stratified. Further work will quantify internal textures and external clast morphologies to determine the relative roles of magmatic and phreatomagmatic fragmentation for the various phases of the eruption. Conference Object Iceland Katla Lancaster University: Lancaster Eprints Katla ENVELOPE(-19.062,-19.062,63.631,63.631) Sólheimajökull ENVELOPE(-19.303,-19.303,63.557,63.557)
institution Open Polar
collection Lancaster University: Lancaster Eprints
op_collection_id ftulancaster
language unknown
description The last eruption of the restless, ice-covered Katla volcanic system in south Iceland was a 1 km3 (DRE) explosive subglacial basaltic event in 1918, which released a 8 km3 meltwater flood. We have sampled both the 1918 jökulhlaup deposit and airfall tephra preserved on Sólheimajökull. Sampling of multiple layers allows examination of discrete phases of eruption/emplacement. Tephra was sieved and clasts thin sectioned to analyse bubble textures, and for compositional analysis using electron probe microanalysis (EPMA) and laser ablation inductively coupled mass spectrometry (LA-ICP-MS). Part of the clasts were analysed for volatile contents using fourier transform infrared spectroscopy (FTIR) and thermogravimetric analysis (TGA). Jökulhlaup samples show evidence of interaction with water; the glass is microlite-poor with ~0.2-0.3 wt.% H2O consistent with quenching under elevated pressure. Some air-fall clasts are microlite rich, completely degassed (~0.1 wt.% H2O) and have interior bubbles that are significantly larger than those at the clast margin. We interpret this as post-fragmentation degassing. These clasts should have taken seconds to cool had they quenched in water. Hot-stage experiments show average bubble growth rates of ~1 µm s-1, suggesting that such clasts have had very little/no interaction with water. Many clasts show repeated episodes of fragmentation and/or degassing, suggesting recycling of material in the upper conduit and/or vent. Preliminary LA-ICP-MS data hints that the magma chamber may have been compositionally stratified. Further work will quantify internal textures and external clast morphologies to determine the relative roles of magmatic and phreatomagmatic fragmentation for the various phases of the eruption.
format Conference Object
author Owen, Jacqueline
Tuffen, Hugh
Coats, Becky
spellingShingle Owen, Jacqueline
Tuffen, Hugh
Coats, Becky
Magma degassing and fragmentation during the 1918 Katla eruption
author_facet Owen, Jacqueline
Tuffen, Hugh
Coats, Becky
author_sort Owen, Jacqueline
title Magma degassing and fragmentation during the 1918 Katla eruption
title_short Magma degassing and fragmentation during the 1918 Katla eruption
title_full Magma degassing and fragmentation during the 1918 Katla eruption
title_fullStr Magma degassing and fragmentation during the 1918 Katla eruption
title_full_unstemmed Magma degassing and fragmentation during the 1918 Katla eruption
title_sort magma degassing and fragmentation during the 1918 katla eruption
publishDate 2015
url https://eprints.lancs.ac.uk/id/eprint/74467/
long_lat ENVELOPE(-19.062,-19.062,63.631,63.631)
ENVELOPE(-19.303,-19.303,63.557,63.557)
geographic Katla
Sólheimajökull
geographic_facet Katla
Sólheimajökull
genre Iceland
Katla
genre_facet Iceland
Katla
op_relation Owen, Jacqueline and Tuffen, Hugh and Coats, Becky (2015) Magma degassing and fragmentation during the 1918 Katla eruption. In: IUGG, 2015-06-222015-07-02.
_version_ 1775352068096131072

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