Reaction of Rhyolitic Magma to its Interception by the IDDP-1 Well, Krafla, 2009

Publikationen: KonferenzbeitragAbstract/Zusammenfassung

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Reaction of Rhyolitic Magma to its Interception by the IDDP-1 Well, Krafla, 2009. / Saubin, Elodie; Nichols, Alex R. L.; Kærgaard Mortensen, Anette et al.
2017. Abstract von AGU Fall Meeting, New Orleans, Louisiana, USA / Vereinigte Staaten.

Publikationen: KonferenzbeitragAbstract/Zusammenfassung

Harvard

Saubin, E, Nichols, ARL, Kærgaard Mortensen, A, Kennedy, BM, Schipper, I, Tuffen, H, Cole, JW, Villeneuve, M, Zierenberg, RA & Watson, T 2017, 'Reaction of Rhyolitic Magma to its Interception by the IDDP-1 Well, Krafla, 2009', AGU Fall Meeting, New Orleans, USA / Vereinigte Staaten, 11/12/17 - 15/12/17.

APA

Saubin, E., Nichols, A. R. L., Kærgaard Mortensen, A., Kennedy, B. M., Schipper, I., Tuffen, H., Cole, J. W., Villeneuve, M., Zierenberg, R. A., & Watson, T. (2017). Reaction of Rhyolitic Magma to its Interception by the IDDP-1 Well, Krafla, 2009. Abstract von AGU Fall Meeting, New Orleans, Louisiana, USA / Vereinigte Staaten.

Vancouver

Saubin E, Nichols ARL, Kærgaard Mortensen A, Kennedy BM, Schipper I, Tuffen H et al.. Reaction of Rhyolitic Magma to its Interception by the IDDP-1 Well, Krafla, 2009. 2017. Abstract von AGU Fall Meeting, New Orleans, Louisiana, USA / Vereinigte Staaten.

Author

Saubin, Elodie ; Nichols, Alex R. L. ; Kærgaard Mortensen, Anette et al. / Reaction of Rhyolitic Magma to its Interception by the IDDP-1 Well, Krafla, 2009. Abstract von AGU Fall Meeting, New Orleans, Louisiana, USA / Vereinigte Staaten.

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@conference{a1729896636a4ef19c9215ff124cb27c,
title = "Reaction of Rhyolitic Magma to its Interception by the IDDP-1 Well, Krafla, 2009",
abstract = "The unexpected encounter of rhyolitic magma during IDDP-1 geothermal borehole drilling at Krafla, Iceland in 2009, temporarily created the world{\textquoteright}s hottest geothermal well. This allowed new questions to be addressed. i) How does magma react to drilling? ii) Are the margins of a magma chamber suitable for long-term extraction of supercritical fluids? To investigate these questions, we aim to reconstruct the degassing and deformation behaviour of the enigmatic magma by looking for correlations between textures in rhyolitic material retrieved from the borehole and the recorded drilling data.During drilling, difficulties were encountered in two zones, at 2070 m and below 2093 m depth. Drilling parameters are consistent with the drill bit encountering a high permeability zone and the contact zone of a magma chamber, respectively. Magma was intercepted three times between 2101-2104.4 m depth, which culminated in an increase in standpipe pressure followed by a decrease in weight on bit interpreted as representing the ascent of magma within the borehole. Circulation returned one hour after the last interception, carrying cuttings of glassy particles, felsite with granophyre and contaminant clasts from drilling, which were sampled as a time-series for the following 9 hours.The nature of glassy particles in this time-series varied through time, with a decrease in the proportion of vesicular clasts and a commensurate increase in dense glassy clasts, transitioning from initially colourless to brown glass. Componentry data show a sporadic decrease in felsite (from 34 wt. %), an increase in glassy particles during the first two hours (from 63 wt. % to 94 wt. %) and an increase in contaminant clasts towards the end of the cutting retrieval period. These temporal variations are probably related to the magma body architecture and interactions with the borehole. Transition from vesicular to dense clasts suggests a change in the degassing process that could be related to an early degassing phase caused by drilling-induced decompressions followed by a fast ascent after the last magma interception. Additional data in terms of shape of clasts, vesicularity, density and water content within glassy particles will link textural data to drilling history in order to investigate degassing history, origin of clasts and quenching pressure.",
author = "Elodie Saubin and Nichols, {Alex R. L.} and {K{\ae}rgaard Mortensen}, Anette and Kennedy, {B. M.} and Ian Schipper and Hugh Tuffen and Cole, {J. W.} and Marlene Villeneuve and Zierenberg, {Robert A} and Tamiko Watson",
year = "2017",
language = "English",
note = "AGU Fall Meeting ; Conference date: 11-12-2017 Through 15-12-2017",

}

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TY - CONF

T1 - Reaction of Rhyolitic Magma to its Interception by the IDDP-1 Well, Krafla, 2009

AU - Saubin, Elodie

AU - Nichols, Alex R. L.

AU - Kærgaard Mortensen, Anette

AU - Kennedy, B. M.

AU - Schipper, Ian

AU - Tuffen, Hugh

AU - Cole, J. W.

AU - Villeneuve, Marlene

AU - Zierenberg, Robert A

AU - Watson, Tamiko

PY - 2017

Y1 - 2017

N2 - The unexpected encounter of rhyolitic magma during IDDP-1 geothermal borehole drilling at Krafla, Iceland in 2009, temporarily created the world’s hottest geothermal well. This allowed new questions to be addressed. i) How does magma react to drilling? ii) Are the margins of a magma chamber suitable for long-term extraction of supercritical fluids? To investigate these questions, we aim to reconstruct the degassing and deformation behaviour of the enigmatic magma by looking for correlations between textures in rhyolitic material retrieved from the borehole and the recorded drilling data.During drilling, difficulties were encountered in two zones, at 2070 m and below 2093 m depth. Drilling parameters are consistent with the drill bit encountering a high permeability zone and the contact zone of a magma chamber, respectively. Magma was intercepted three times between 2101-2104.4 m depth, which culminated in an increase in standpipe pressure followed by a decrease in weight on bit interpreted as representing the ascent of magma within the borehole. Circulation returned one hour after the last interception, carrying cuttings of glassy particles, felsite with granophyre and contaminant clasts from drilling, which were sampled as a time-series for the following 9 hours.The nature of glassy particles in this time-series varied through time, with a decrease in the proportion of vesicular clasts and a commensurate increase in dense glassy clasts, transitioning from initially colourless to brown glass. Componentry data show a sporadic decrease in felsite (from 34 wt. %), an increase in glassy particles during the first two hours (from 63 wt. % to 94 wt. %) and an increase in contaminant clasts towards the end of the cutting retrieval period. These temporal variations are probably related to the magma body architecture and interactions with the borehole. Transition from vesicular to dense clasts suggests a change in the degassing process that could be related to an early degassing phase caused by drilling-induced decompressions followed by a fast ascent after the last magma interception. Additional data in terms of shape of clasts, vesicularity, density and water content within glassy particles will link textural data to drilling history in order to investigate degassing history, origin of clasts and quenching pressure.

AB - The unexpected encounter of rhyolitic magma during IDDP-1 geothermal borehole drilling at Krafla, Iceland in 2009, temporarily created the world’s hottest geothermal well. This allowed new questions to be addressed. i) How does magma react to drilling? ii) Are the margins of a magma chamber suitable for long-term extraction of supercritical fluids? To investigate these questions, we aim to reconstruct the degassing and deformation behaviour of the enigmatic magma by looking for correlations between textures in rhyolitic material retrieved from the borehole and the recorded drilling data.During drilling, difficulties were encountered in two zones, at 2070 m and below 2093 m depth. Drilling parameters are consistent with the drill bit encountering a high permeability zone and the contact zone of a magma chamber, respectively. Magma was intercepted three times between 2101-2104.4 m depth, which culminated in an increase in standpipe pressure followed by a decrease in weight on bit interpreted as representing the ascent of magma within the borehole. Circulation returned one hour after the last interception, carrying cuttings of glassy particles, felsite with granophyre and contaminant clasts from drilling, which were sampled as a time-series for the following 9 hours.The nature of glassy particles in this time-series varied through time, with a decrease in the proportion of vesicular clasts and a commensurate increase in dense glassy clasts, transitioning from initially colourless to brown glass. Componentry data show a sporadic decrease in felsite (from 34 wt. %), an increase in glassy particles during the first two hours (from 63 wt. % to 94 wt. %) and an increase in contaminant clasts towards the end of the cutting retrieval period. These temporal variations are probably related to the magma body architecture and interactions with the borehole. Transition from vesicular to dense clasts suggests a change in the degassing process that could be related to an early degassing phase caused by drilling-induced decompressions followed by a fast ascent after the last magma interception. Additional data in terms of shape of clasts, vesicularity, density and water content within glassy particles will link textural data to drilling history in order to investigate degassing history, origin of clasts and quenching pressure.

M3 - Abstract

T2 - AGU Fall Meeting

Y2 - 11 December 2017 through 15 December 2017

ER -