Varying processes, similar results: how composition influences fragmentation and subsequent feeding of large pyroclastic density currents
Unlike their silicic counterparts, mafic eruptions are known for being on the low-end of the explosivity spectrum with eruption styles commonly ranging from effusive to Hawaiian fire fountaining. However, there are increasing discoveries of large mafic Plinian eruptions, sometimes generating ignimbr...
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Science::Geology Pyroclastic Density Currents Mafic Ignimbrite |
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Science::Geology Pyroclastic Density Currents Mafic Ignimbrite Bernard, Olivier Bouvet de Maisonneuve, Caroline Arbaret, Laurent Nagashima, Kazuhide Oalmann, Jeffrey Prabowo, Arief Ratdomopurbo, Antonius Varying processes, similar results: how composition influences fragmentation and subsequent feeding of large pyroclastic density currents |
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Unlike their silicic counterparts, mafic eruptions are known for being on the low-end of the explosivity spectrum with eruption styles commonly ranging from effusive to Hawaiian fire fountaining. However, there are increasing discoveries of large mafic Plinian eruptions, sometimes generating ignimbrites, suggesting that this phenomenon might not be so uncommon. So, what processes lead a mafic magma to fragment violently enough to generate extensive ignimbrites? We sampled pumices from ignimbrites and PDCs with a compositional range from basaltic-andesite (Curacautín ignimbrite, Volcàn Llaima, Chile), andesite (Marapi, Indonesia) to trachyte (Gunungkawi ignimbrite, Batur, Indonesia). We use SEM imagery and X-ray Microtomography on pyroclasts from these deposits to characterize phenocryst, microlite and vesicle textures. From vesicle number densities we estimate fragmentation decompression rates in the range of 0.4–1.6 MPa/s for the three deposits. With a combination of EPMA and SIMS analyses we characterise pre-eruptive storage conditions. Based on the bulk and groundmass compositions, the storage temperature (1,050–1,100°C), pressure (50–100 MPa) and phenocryst content (1.0–2.5 vol%), we conclude that the basaltic-andesitic Curacautín magma was at sub-liquidus conditions, which allowed fast and widespread disequilibrium matrix crystallization (0–80 vol%) during ascent to the surface. Combined with the important decompression rate, this intense crystallization led to a magma bulk viscosity jump from 103 up to >107 Pa s and allowed it to fragment brittlely. Conversely, for the Marapi PDC and Gunungkawi ignimbrite, similar decompression rates coupled with larger initial bulk viscosities of 105–106 Pa s were sufficient to fragment the magma brittlely. The fragmentation processes for these latter two deposits were slightly different however, with the Marapi PDC fragmentation being mostly driven by vesicle overpressure, while a combination of bubble overpressure and intense strain-rate were the cause of fragmentation for the Gunungkawi ignimbrite. We conclude that mafic ignimbrites can form due to a combination of peculiar storage conditions that lead to strongly non-linear feedback processes in the conduit, particularly intense microlite crystallization on very short timescales coupled with intense decompression rates. Conversely, the high viscosity determined by pre-eruptive storage conditions, including temperature and volatile-content, are key in controlling the formation of more evolved magmas PDCs'. |
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Asian School of the Environment |
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Asian School of the Environment Bernard, Olivier Bouvet de Maisonneuve, Caroline Arbaret, Laurent Nagashima, Kazuhide Oalmann, Jeffrey Prabowo, Arief Ratdomopurbo, Antonius |
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Bernard, Olivier Bouvet de Maisonneuve, Caroline Arbaret, Laurent Nagashima, Kazuhide Oalmann, Jeffrey Prabowo, Arief Ratdomopurbo, Antonius |
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Bernard, Olivier |
| title |
Varying processes, similar results: how composition influences fragmentation and subsequent feeding of large pyroclastic density currents |
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Varying processes, similar results: how composition influences fragmentation and subsequent feeding of large pyroclastic density currents |
| title_full |
Varying processes, similar results: how composition influences fragmentation and subsequent feeding of large pyroclastic density currents |
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Varying processes, similar results: how composition influences fragmentation and subsequent feeding of large pyroclastic density currents |
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Varying processes, similar results: how composition influences fragmentation and subsequent feeding of large pyroclastic density currents |
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varying processes, similar results: how composition influences fragmentation and subsequent feeding of large pyroclastic density currents |
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2023 |
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https://hdl.handle.net/10356/164752 |
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sg-ntu-dr.10356-1647522023-02-18T23:31:39Z Varying processes, similar results: how composition influences fragmentation and subsequent feeding of large pyroclastic density currents Bernard, Olivier Bouvet de Maisonneuve, Caroline Arbaret, Laurent Nagashima, Kazuhide Oalmann, Jeffrey Prabowo, Arief Ratdomopurbo, Antonius Asian School of the Environment Earth Observatory of Singapore Science::Geology Pyroclastic Density Currents Mafic Ignimbrite Unlike their silicic counterparts, mafic eruptions are known for being on the low-end of the explosivity spectrum with eruption styles commonly ranging from effusive to Hawaiian fire fountaining. However, there are increasing discoveries of large mafic Plinian eruptions, sometimes generating ignimbrites, suggesting that this phenomenon might not be so uncommon. So, what processes lead a mafic magma to fragment violently enough to generate extensive ignimbrites? We sampled pumices from ignimbrites and PDCs with a compositional range from basaltic-andesite (Curacautín ignimbrite, Volcàn Llaima, Chile), andesite (Marapi, Indonesia) to trachyte (Gunungkawi ignimbrite, Batur, Indonesia). We use SEM imagery and X-ray Microtomography on pyroclasts from these deposits to characterize phenocryst, microlite and vesicle textures. From vesicle number densities we estimate fragmentation decompression rates in the range of 0.4–1.6 MPa/s for the three deposits. With a combination of EPMA and SIMS analyses we characterise pre-eruptive storage conditions. Based on the bulk and groundmass compositions, the storage temperature (1,050–1,100°C), pressure (50–100 MPa) and phenocryst content (1.0–2.5 vol%), we conclude that the basaltic-andesitic Curacautín magma was at sub-liquidus conditions, which allowed fast and widespread disequilibrium matrix crystallization (0–80 vol%) during ascent to the surface. Combined with the important decompression rate, this intense crystallization led to a magma bulk viscosity jump from 103 up to >107 Pa s and allowed it to fragment brittlely. Conversely, for the Marapi PDC and Gunungkawi ignimbrite, similar decompression rates coupled with larger initial bulk viscosities of 105–106 Pa s were sufficient to fragment the magma brittlely. The fragmentation processes for these latter two deposits were slightly different however, with the Marapi PDC fragmentation being mostly driven by vesicle overpressure, while a combination of bubble overpressure and intense strain-rate were the cause of fragmentation for the Gunungkawi ignimbrite. We conclude that mafic ignimbrites can form due to a combination of peculiar storage conditions that lead to strongly non-linear feedback processes in the conduit, particularly intense microlite crystallization on very short timescales coupled with intense decompression rates. Conversely, the high viscosity determined by pre-eruptive storage conditions, including temperature and volatile-content, are key in controlling the formation of more evolved magmas PDCs'. Ministry of Education (MOE) National Research Foundation (NRF) Published version This work was supported by the National Research Foundation Singapore and the Singapore Ministry of Education under the Research Centres of Excellence initiative as well as the National Research Foundation of Singapore, grant NRF-NRFF2016-04. 2023-02-13T06:40:14Z 2023-02-13T06:40:14Z 2022 Journal Article Bernard, O., Bouvet de Maisonneuve, C., Arbaret, L., Nagashima, K., Oalmann, J., Prabowo, A. & Ratdomopurbo, A. (2022). Varying processes, similar results: how composition influences fragmentation and subsequent feeding of large pyroclastic density currents. Frontiers in Earth Science, 10, 979210-. https://dx.doi.org/10.3389/feart.2022.979210 2296-6463 https://hdl.handle.net/10356/164752 10.3389/feart.2022.979210 2-s2.0-85139245171 10 979210 en NRF-NRFF2016-04 Frontiers in Earth Science © 2022 Bernard, Bouvet de Maisonneuve, Arbaret, Nagashima, Oalmann, Prabowo and Ratdomopurbo. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms. application/pdf |