The rheology of rhyolite magma from the IDDP-1 borehole and Hrafntinnuhryggur (Krafla, Iceland) with implications for geothermal drilling

Lancaster Environment Centre

Electronic data

VOLGEO-D-24-00113_R1
Accepted author manuscript, 13.1 MB, PDF document
Available under license: CC BY: Creative Commons Attribution 4.0 International License

Text available via DOI:

https://doi.org/10.1016/j.jvolgeores.2024.108159
Final published version
Available under license: CC BY: Creative Commons Attribution 4.0 International License

View graph of relations

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Published

Standard

The rheology of rhyolite magma from the IDDP-1 borehole and Hrafntinnuhryggur (Krafla, Iceland) with implications for geothermal drilling. / Wadsworth, F.B.; Vasseur, Jéremie ; Lavallée, Yan et al.
In: Journal of Volcanology and Geothermal Research, Vol. 455, 108159, 30.11.2024.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Harvard

Wadsworth, FB, Vasseur, J, Lavallée, Y, Weidendorfer, D, Rooyakkers, SM, Foster, A, Jackson, LE, Kennedy, BM, Nichols, ARL, Schipper, CI, Scheu, B, Dingwell, DB, Watson, T, Rule, G, Witcher, T & Tuffen, H 2024, 'The rheology of rhyolite magma from the IDDP-1 borehole and Hrafntinnuhryggur (Krafla, Iceland) with implications for geothermal drilling', Journal of Volcanology and Geothermal Research, vol. 455, 108159. https://doi.org/10.1016/j.jvolgeores.2024.108159

APA

Wadsworth, F. B., Vasseur, J., Lavallée, Y., Weidendorfer, D., Rooyakkers, S. M., Foster, A., Jackson, L. E., Kennedy, B. M., Nichols, A. R. L., Schipper, C. I., Scheu, B., Dingwell, D. B., Watson, T., Rule, G., Witcher, T., & Tuffen, H. (2024). The rheology of rhyolite magma from the IDDP-1 borehole and Hrafntinnuhryggur (Krafla, Iceland) with implications for geothermal drilling. Journal of Volcanology and Geothermal Research, 455, Article 108159. https://doi.org/10.1016/j.jvolgeores.2024.108159

Vancouver

Wadsworth FB, Vasseur J, Lavallée Y, Weidendorfer D, Rooyakkers SM, Foster A et al. The rheology of rhyolite magma from the IDDP-1 borehole and Hrafntinnuhryggur (Krafla, Iceland) with implications for geothermal drilling. Journal of Volcanology and Geothermal Research. 2024 Nov 30;455:108159. Epub 2024 Sept 10. doi: 10.1016/j.jvolgeores.2024.108159

Author

Wadsworth, F.B. ; Vasseur, Jéremie ; Lavallée, Yan et al. / The rheology of rhyolite magma from the IDDP-1 borehole and Hrafntinnuhryggur (Krafla, Iceland) with implications for geothermal drilling. In: Journal of Volcanology and Geothermal Research. 2024 ; Vol. 455.

Bibtex

@article{13790af0cfc64c48a56c4651b9edb8e9,

title = "The rheology of rhyolite magma from the IDDP-1 borehole and Hrafntinnuhryggur (Krafla, Iceland) with implications for geothermal drilling",

abstract = "Changes in rhyolite melt viscosity during magma decompression and degassing exert a first order control on ascent through the crust and volcanic eruption style. These changes have as yet unknown hazard implications for geothermal drilling in pursuit of particularly hot fluids close to magma storage regions. Here, we exploit the situation at Krafla volcano in which rhyolite has both erupted at Earth's surface and been sampled at shallow storage depths via drilling of the 2009 IDDP-1 and 2008 KJ-39 boreholes. We use differential scanning calorimetry to constrain that the IDDP-1 magma quenched to glass at ∼ 700 K, at a rate of between 7 and 80 K.min−1. We measure the equilibrium viscosity of the IDDP-1 rhyolite at temperatures close to the glass transition interval and show that the rhyolite viscosity is consistent with generalized viscosity models assuming a dissolved concentration of wt%. We couple these results with micro-penetration and concentric cylinder rheometry over a range of potential magma storage temperatures to constrain the response of surficial Krafla rhyolites to stress. The surficial rhyolites at Krafla match the same viscosity model, assuming a lower dissolved concentration of wt%. Our results show that at a storage temperature of 1123–1193 K, the viscosity of the stored magma is ∼ 3×105 Pa.s. At the same temperature, the viscosity following degassing during ascent to the surface rises to ∼ 2×109 Pa.s. Finally, we use high-stress compression tests on the Hrafntinnuhryggur surface obsidian to determine the onset of unrelaxed behavior and viscoelastic melt rupture or fragmentation pertinent to understanding the melt response to rapid pressure changes that may be associated with further (near-) magma exploration at Krafla. Taken together, we characterize the relaxation and viscosity of these magmas from source-to-surface.",

author = "F.B. Wadsworth and J{\'e}remie Vasseur and Yan Lavall{\'e}e and Daniel Weidendorfer and S.M. Rooyakkers and Annabelle Foster and Jackson, {Lucy E} and Kennedy, {Ben M.} and Nichols, {Alexander R. L.} and Schipper, {C. Ian} and Bettina Scheu and Dingwell, {Donald B} and Tamiko Watson and Georgina Rule and Taylor Witcher and Hugh Tuffen",

year = "2024",

month = nov,

day = "30",

doi = "10.1016/j.jvolgeores.2024.108159",

language = "English",

volume = "455",

journal = "Journal of Volcanology and Geothermal Research",

issn = "0377-0273",

publisher = "Elsevier Science B.V.",

}

RIS

TY - JOUR

T1 - The rheology of rhyolite magma from the IDDP-1 borehole and Hrafntinnuhryggur (Krafla, Iceland) with implications for geothermal drilling

AU - Wadsworth, F.B.

AU - Vasseur, Jéremie

AU - Lavallée, Yan

AU - Weidendorfer, Daniel

AU - Rooyakkers, S.M.

AU - Foster, Annabelle

AU - Jackson, Lucy E

AU - Kennedy, Ben M.

AU - Nichols, Alexander R. L.

AU - Schipper, C. Ian

AU - Scheu, Bettina

AU - Dingwell, Donald B

AU - Watson, Tamiko

AU - Rule, Georgina

AU - Witcher, Taylor

AU - Tuffen, Hugh

PY - 2024/11/30

Y1 - 2024/11/30

N2 - Changes in rhyolite melt viscosity during magma decompression and degassing exert a first order control on ascent through the crust and volcanic eruption style. These changes have as yet unknown hazard implications for geothermal drilling in pursuit of particularly hot fluids close to magma storage regions. Here, we exploit the situation at Krafla volcano in which rhyolite has both erupted at Earth's surface and been sampled at shallow storage depths via drilling of the 2009 IDDP-1 and 2008 KJ-39 boreholes. We use differential scanning calorimetry to constrain that the IDDP-1 magma quenched to glass at ∼ 700 K, at a rate of between 7 and 80 K.min−1. We measure the equilibrium viscosity of the IDDP-1 rhyolite at temperatures close to the glass transition interval and show that the rhyolite viscosity is consistent with generalized viscosity models assuming a dissolved concentration of wt%. We couple these results with micro-penetration and concentric cylinder rheometry over a range of potential magma storage temperatures to constrain the response of surficial Krafla rhyolites to stress. The surficial rhyolites at Krafla match the same viscosity model, assuming a lower dissolved concentration of wt%. Our results show that at a storage temperature of 1123–1193 K, the viscosity of the stored magma is ∼ 3×105 Pa.s. At the same temperature, the viscosity following degassing during ascent to the surface rises to ∼ 2×109 Pa.s. Finally, we use high-stress compression tests on the Hrafntinnuhryggur surface obsidian to determine the onset of unrelaxed behavior and viscoelastic melt rupture or fragmentation pertinent to understanding the melt response to rapid pressure changes that may be associated with further (near-) magma exploration at Krafla. Taken together, we characterize the relaxation and viscosity of these magmas from source-to-surface.

AB - Changes in rhyolite melt viscosity during magma decompression and degassing exert a first order control on ascent through the crust and volcanic eruption style. These changes have as yet unknown hazard implications for geothermal drilling in pursuit of particularly hot fluids close to magma storage regions. Here, we exploit the situation at Krafla volcano in which rhyolite has both erupted at Earth's surface and been sampled at shallow storage depths via drilling of the 2009 IDDP-1 and 2008 KJ-39 boreholes. We use differential scanning calorimetry to constrain that the IDDP-1 magma quenched to glass at ∼ 700 K, at a rate of between 7 and 80 K.min−1. We measure the equilibrium viscosity of the IDDP-1 rhyolite at temperatures close to the glass transition interval and show that the rhyolite viscosity is consistent with generalized viscosity models assuming a dissolved concentration of wt%. We couple these results with micro-penetration and concentric cylinder rheometry over a range of potential magma storage temperatures to constrain the response of surficial Krafla rhyolites to stress. The surficial rhyolites at Krafla match the same viscosity model, assuming a lower dissolved concentration of wt%. Our results show that at a storage temperature of 1123–1193 K, the viscosity of the stored magma is ∼ 3×105 Pa.s. At the same temperature, the viscosity following degassing during ascent to the surface rises to ∼ 2×109 Pa.s. Finally, we use high-stress compression tests on the Hrafntinnuhryggur surface obsidian to determine the onset of unrelaxed behavior and viscoelastic melt rupture or fragmentation pertinent to understanding the melt response to rapid pressure changes that may be associated with further (near-) magma exploration at Krafla. Taken together, we characterize the relaxation and viscosity of these magmas from source-to-surface.

U2 - 10.1016/j.jvolgeores.2024.108159

DO - 10.1016/j.jvolgeores.2024.108159

M3 - Journal article

VL - 455

JO - Journal of Volcanology and Geothermal Research

JF - Journal of Volcanology and Geothermal Research

SN - 0377-0273

M1 - 108159

ER -

Research

Electronic data

Links

Text available via DOI: