Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia)

Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia)

Understanding the thermal behavior of pyroclastic density currents (PDCs) is crucial for forecasting impact scenarios for exposed populations as it affects their lethality and destructiveness. Here we report the emplacement temperatures of PDC deposits produced during the paroxysmal explosive erupti...

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Main Authors: Trolese, M., Giordano, G., Komorowski, J. C., Jenkins, Susanna F., Baxter, P. J., Cholik, N., Raditya, P., Corrado, S.
Other Authors: Asian School of the Environment
Format: Article
Language:English
Published: 2020
Subjects:
Science::Geology
Merapi Volcano
Pyroclastic Density Current
Online Access:https://hdl.handle.net/10356/139833
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1398332020-09-26T21:30:17Z Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia) Trolese, M. Giordano, G. Komorowski, J. C. Jenkins, Susanna F. Baxter, P. J. Cholik, N. Raditya, P. Corrado, S. Asian School of the Environment Earth Observatory of Singapore Science::Geology Merapi Volcano Pyroclastic Density Current Understanding the thermal behavior of pyroclastic density currents (PDCs) is crucial for forecasting impact scenarios for exposed populations as it affects their lethality and destructiveness. Here we report the emplacement temperatures of PDC deposits produced during the paroxysmal explosive eruption of Merapi (Central Java) on 5 November 2010 based on the reflectance of entombed charcoal fragments. This event was anomalously explosive for Merapi, and destroyed the summit dome that had been rapidly growing, with partial collapses and associated PDCs, since October 26. Results show mean reflectance values mainly between 0.17 and 0.41. These new data provide a minimum temperature of the flow of 240–320 °C, consistent with previous estimations determined from independent field, engineering, and medical observations published in the literature for this eruption. A few charcoal fragments recorded higher values, suggestive of temperatures up to 450 °C, and we suggest that this is due to the thermal disequilibrium of the deposits, with larger block-size clasts being much hotter than the surrounding ash matrix. Charring temperatures show no major differences between proximal and distal PDC deposits and are significantly lower than those that may be associated with a fast growing dome dominated by dense and vitric non-vesicular rocks. We therefore infer that the decrease in temperature from that at fragmentation (>900 °C) occurred in the very initial part of the current, <2 km from source. We discuss possible processes that allow the very fast cooling of these energetic PDCs, as well as the conservative thermal behavior shown during the depositional phase, across the entire depositional area. Accepted version 2020-05-22T03:28:39Z 2020-05-22T03:28:39Z 2018 Journal Article Trolese, M., Giordano, G., Komorowski, J. C., Jenkins, S. F., Baxter, P. J., Cholik, N., . . ., Corrado, S. (2018). Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia). Journal of Volcanology and Geothermal Research, 358, 1-12. doi:10.1016/j.jvolgeores.2018.06.004 0377-0273 https://hdl.handle.net/10356/139833 10.1016/j.jvolgeores.2018.06.004 2-s2.0-85048791801 358 1 12 en Journal of Volcanology and Geothermal Research © 2018 Elsevier B.V. This paper was published in Journal of Volcanology and Geothermal Research and is made available with permission of Elsevier B.V. application/pdf
institution Nanyang Technological University
building NTU Library
country Singapore
collection DR-NTU
language English
topic Science::Geology
Merapi Volcano
Pyroclastic Density Current
spellingShingle Science::Geology
Merapi Volcano
Pyroclastic Density Current
Trolese, M.
Giordano, G.
Komorowski, J. C.
Jenkins, Susanna F.
Baxter, P. J.
Cholik, N.
Raditya, P.
Corrado, S.
Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia)
description Understanding the thermal behavior of pyroclastic density currents (PDCs) is crucial for forecasting impact scenarios for exposed populations as it affects their lethality and destructiveness. Here we report the emplacement temperatures of PDC deposits produced during the paroxysmal explosive eruption of Merapi (Central Java) on 5 November 2010 based on the reflectance of entombed charcoal fragments. This event was anomalously explosive for Merapi, and destroyed the summit dome that had been rapidly growing, with partial collapses and associated PDCs, since October 26. Results show mean reflectance values mainly between 0.17 and 0.41. These new data provide a minimum temperature of the flow of 240–320 °C, consistent with previous estimations determined from independent field, engineering, and medical observations published in the literature for this eruption. A few charcoal fragments recorded higher values, suggestive of temperatures up to 450 °C, and we suggest that this is due to the thermal disequilibrium of the deposits, with larger block-size clasts being much hotter than the surrounding ash matrix. Charring temperatures show no major differences between proximal and distal PDC deposits and are significantly lower than those that may be associated with a fast growing dome dominated by dense and vitric non-vesicular rocks. We therefore infer that the decrease in temperature from that at fragmentation (>900 °C) occurred in the very initial part of the current, <2 km from source. We discuss possible processes that allow the very fast cooling of these energetic PDCs, as well as the conservative thermal behavior shown during the depositional phase, across the entire depositional area.
author2 Asian School of the Environment
author_facet Asian School of the Environment
Trolese, M.
Giordano, G.
Komorowski, J. C.
Jenkins, Susanna F.
Baxter, P. J.
Cholik, N.
Raditya, P.
Corrado, S.
format Article
author Trolese, M.
Giordano, G.
Komorowski, J. C.
Jenkins, Susanna F.
Baxter, P. J.
Cholik, N.
Raditya, P.
Corrado, S.
author_sort Trolese, M.
title Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia)
title_short Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia)
title_full Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia)
title_fullStr Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia)
title_full_unstemmed Very rapid cooling of the energetic pyroclastic density currents associated with the 5 November 2010 Merapi eruption (Indonesia)
title_sort very rapid cooling of the energetic pyroclastic density currents associated with the 5 november 2010 merapi eruption (indonesia)
publishDate 2020
url https://hdl.handle.net/10356/139833
_version_ 1681057640380104704

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