Quantifying the Water‐to‐Melt Mass Ratio and Its Impact on Eruption Plumes During Explosive Hydromagmatic Eruptions
The interaction of magma with external water commonly enhances magma fragmentation through the conversion of thermal to mechanical energy and results in an increased production of fine-grained volcanic tephra. Magma-water interaction is thus of importance for hazard mitigation on both a local and a...
| Published in: | Geochemistry, Geophysics, Geosystems |
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| Main Authors: | , , , , |
| Format: | Article in Journal/Newspaper |
| Language: | unknown |
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2022
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| Online Access: | https://eprints.lancs.ac.uk/id/eprint/176218/ https://doi.org/10.1029/2021gc010160 |
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ftulancaster:oai:eprints.lancs.ac.uk:176218 |
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ftulancaster:oai:eprints.lancs.ac.uk:176218 2023-08-27T04:10:14+02:00 Quantifying the Water‐to‐Melt Mass Ratio and Its Impact on Eruption Plumes During Explosive Hydromagmatic Eruptions Hajimirza, Sahand Jones, Thomas J. Moreland, William M. Gonnermann, Helge M. Thordarson, Thor 2022-05-31 https://eprints.lancs.ac.uk/id/eprint/176218/ https://doi.org/10.1029/2021gc010160 unknown Hajimirza, Sahand and Jones, Thomas J. and Moreland, William M. and Gonnermann, Helge M. and Thordarson, Thor (2022) Quantifying the Water‐to‐Melt Mass Ratio and Its Impact on Eruption Plumes During Explosive Hydromagmatic Eruptions. Geochemistry, Geophysics, Geosystems, 23 (5). ISSN 1525-2027 Journal Article PeerReviewed 2022 ftulancaster https://doi.org/10.1029/2021gc010160 2023-08-03T22:42:04Z The interaction of magma with external water commonly enhances magma fragmentation through the conversion of thermal to mechanical energy and results in an increased production of fine-grained volcanic tephra. Magma-water interaction is thus of importance for hazard mitigation on both a local and a regional scales. The relative proportion of water that interacts with magma, quantified as the water-to-melt mass ratio, is thought to determine the efficiency of thermal to mechanical energy conversion, termed the fragmentation efficiency. Here, we analyze the pyroclast size distributions from the 10th century Eldgjá fissure eruption in Iceland, where parts of the fissure erupted subglacially and other erupted subaerially. The subglacially erupted magma passed through a column of glacial meltwater, resulting in a larger proportion of finer pyroclast sizes relative to the subaerially erupted, purely magmatic tephra. This finer grain size distribution has been attributed to quench-granulation induced by enhanced cooling upon interaction with external water. We hypothesize that the additional fragmentation (surface) energy required to produce the finer grained hydromagmatic deposits is due to the conversion of thermal to mechanical energy associated with the entrainment of water into the volcanic jet, as it passed through a column of subglacial melt water. Based on field and granulometry data, we estimate that the interaction of the volcanic jet with the meltwater provided an additional fragmentation energy of approximately 3–14 kJ per kg of pyroclasts. We numerically model the hydrofragmentation energy within a jet that passes through a layer of meltwater. We find that the water-to-melt mass ratio of entrained water required to produce the additional fragmentation energy is in the range of 1–2, which requires a minimum ice melting rate of 104 m3 s−1. Our simulation results show that the water-to-melt ratio is an important parameter that controls the ascent of plume in the atmosphere. Article in Journal/Newspaper Iceland Lancaster University: Lancaster Eprints Eldgjá ENVELOPE(-18.608,-18.608,63.962,63.962) Geochemistry, Geophysics, Geosystems 23 5 |
| institution |
Open Polar |
| collection |
Lancaster University: Lancaster Eprints |
| op_collection_id |
ftulancaster |
| language |
unknown |
| description |
The interaction of magma with external water commonly enhances magma fragmentation through the conversion of thermal to mechanical energy and results in an increased production of fine-grained volcanic tephra. Magma-water interaction is thus of importance for hazard mitigation on both a local and a regional scales. The relative proportion of water that interacts with magma, quantified as the water-to-melt mass ratio, is thought to determine the efficiency of thermal to mechanical energy conversion, termed the fragmentation efficiency. Here, we analyze the pyroclast size distributions from the 10th century Eldgjá fissure eruption in Iceland, where parts of the fissure erupted subglacially and other erupted subaerially. The subglacially erupted magma passed through a column of glacial meltwater, resulting in a larger proportion of finer pyroclast sizes relative to the subaerially erupted, purely magmatic tephra. This finer grain size distribution has been attributed to quench-granulation induced by enhanced cooling upon interaction with external water. We hypothesize that the additional fragmentation (surface) energy required to produce the finer grained hydromagmatic deposits is due to the conversion of thermal to mechanical energy associated with the entrainment of water into the volcanic jet, as it passed through a column of subglacial melt water. Based on field and granulometry data, we estimate that the interaction of the volcanic jet with the meltwater provided an additional fragmentation energy of approximately 3–14 kJ per kg of pyroclasts. We numerically model the hydrofragmentation energy within a jet that passes through a layer of meltwater. We find that the water-to-melt mass ratio of entrained water required to produce the additional fragmentation energy is in the range of 1–2, which requires a minimum ice melting rate of 104 m3 s−1. Our simulation results show that the water-to-melt ratio is an important parameter that controls the ascent of plume in the atmosphere. |
| format |
Article in Journal/Newspaper |
| author |
Hajimirza, Sahand Jones, Thomas J. Moreland, William M. Gonnermann, Helge M. Thordarson, Thor |
| spellingShingle |
Hajimirza, Sahand Jones, Thomas J. Moreland, William M. Gonnermann, Helge M. Thordarson, Thor Quantifying the Water‐to‐Melt Mass Ratio and Its Impact on Eruption Plumes During Explosive Hydromagmatic Eruptions |
| author_facet |
Hajimirza, Sahand Jones, Thomas J. Moreland, William M. Gonnermann, Helge M. Thordarson, Thor |
| author_sort |
Hajimirza, Sahand |
| title |
Quantifying the Water‐to‐Melt Mass Ratio and Its Impact on Eruption Plumes During Explosive Hydromagmatic Eruptions |
| title_short |
Quantifying the Water‐to‐Melt Mass Ratio and Its Impact on Eruption Plumes During Explosive Hydromagmatic Eruptions |
| title_full |
Quantifying the Water‐to‐Melt Mass Ratio and Its Impact on Eruption Plumes During Explosive Hydromagmatic Eruptions |
| title_fullStr |
Quantifying the Water‐to‐Melt Mass Ratio and Its Impact on Eruption Plumes During Explosive Hydromagmatic Eruptions |
| title_full_unstemmed |
Quantifying the Water‐to‐Melt Mass Ratio and Its Impact on Eruption Plumes During Explosive Hydromagmatic Eruptions |
| title_sort |
quantifying the water‐to‐melt mass ratio and its impact on eruption plumes during explosive hydromagmatic eruptions |
| publishDate |
2022 |
| url |
https://eprints.lancs.ac.uk/id/eprint/176218/ https://doi.org/10.1029/2021gc010160 |
| long_lat |
ENVELOPE(-18.608,-18.608,63.962,63.962) |
| geographic |
Eldgjá |
| geographic_facet |
Eldgjá |
| genre |
Iceland |
| genre_facet |
Iceland |
| op_relation |
Hajimirza, Sahand and Jones, Thomas J. and Moreland, William M. and Gonnermann, Helge M. and Thordarson, Thor (2022) Quantifying the Water‐to‐Melt Mass Ratio and Its Impact on Eruption Plumes During Explosive Hydromagmatic Eruptions. Geochemistry, Geophysics, Geosystems, 23 (5). ISSN 1525-2027 |
| op_doi |
https://doi.org/10.1029/2021gc010160 |
| container_title |
Geochemistry, Geophysics, Geosystems |
| container_volume |
23 |
| container_issue |
5 |
| _version_ |
1775352102186385408 |