Increasing the Permeability of Hydrothermally Altered Andesite by Transitory Heating

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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Increasing the Permeability of Hydrothermally Altered Andesite by Transitory Heating. / Mordensky, S. P.; Kennedy, B. M.; Villeneuve, M. C. et al.
in: Geochemistry, geophysics, geosystems, Jahrgang 20.2019, Nr. 11, 01.11.2019, S. 5251-5269.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Harvard

Mordensky, SP, Kennedy, BM, Villeneuve, MC, Lavallée, Y, Reichow, MK, Wallace, PA, Siratovich, PA & Gravley, DM 2019, 'Increasing the Permeability of Hydrothermally Altered Andesite by Transitory Heating', Geochemistry, geophysics, geosystems, Jg. 20.2019, Nr. 11, S. 5251-5269. https://doi.org/10.1029/2019GC008409

APA

Mordensky, S. P., Kennedy, B. M., Villeneuve, M. C., Lavallée, Y., Reichow, M. K., Wallace, P. A., Siratovich, P. A., & Gravley, D. M. (2019). Increasing the Permeability of Hydrothermally Altered Andesite by Transitory Heating. Geochemistry, geophysics, geosystems, 20.2019(11), 5251-5269. https://doi.org/10.1029/2019GC008409

Vancouver

Mordensky SP, Kennedy BM, Villeneuve MC, Lavallée Y, Reichow MK, Wallace PA et al. Increasing the Permeability of Hydrothermally Altered Andesite by Transitory Heating. Geochemistry, geophysics, geosystems. 2019 Nov 1;20.2019(11):5251-5269. doi: 10.1029/2019GC008409

Author

Mordensky, S. P. ; Kennedy, B. M. ; Villeneuve, M. C. et al. / Increasing the Permeability of Hydrothermally Altered Andesite by Transitory Heating. in: Geochemistry, geophysics, geosystems. 2019 ; Jahrgang 20.2019, Nr. 11. S. 5251-5269.

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@article{e0da66eb315c4cc4802a84690e950bc2,
title = "Increasing the Permeability of Hydrothermally Altered Andesite by Transitory Heating",
abstract = "Changes in permeability can impact geological processes, geohazards, and geothermal energy production. In hydrothermal systems, high-temperature heat sources drive fluid convection through the pore network of reservoir rocks. Additionally, thermal fluctuations may induce microfracturing and affect the mineralogical stability of the reservoir rock, thus modifying the fluid pathways and affecting permeability and strength. This study describes the results of thermal heating events lasting several hours on a “moderately altered” plagioclase-clinochlore-calcite-quartz andesite and a “highly altered” plagioclase-clinozoisite-quartz-clinochlore andesite from the Rotokawa Geothermal Field, New Zealand. We use a low thermal gradient (~1.2 °C/min) in an H2O-saturated, 20-MPa pressure environment to constrain changes in petrophysical properties associated with transitory thermal phenomena between 350 and 739 °C. As the treatment temperature increases, the mass reduces, while porosity and permeability increase. These effects were greater in the “moderately altered” andesite than in the “highly altered” andesite. Microfracturing is responsible for these changes at lower temperatures (e.g., ≤400 °C). At higher temperatures (e.g., >400 °C), microfracturing remains partially responsible for these rock property changes (e.g., higher permeability); however, these changes are also a product of clinochlore, quartz, and (when present) calcite reacting out of the altered andesite, and increasing porosity. We propose that at temperatures >400 °C, volumetric phase changes associated with heat-driven reactions in a wet environment can contribute to microcracking and porosity/permeability changes. Our data support observations where high-temperature conditions at the margins of magma bodies can be associated with substantial increased permeability and decreased strength.",
keywords = "Altered andesite, Hydrothermal alteration, permeability, porosity, rotokawa andesite, Thermal treatment",
author = "Mordensky, {S. P.} and Kennedy, {B. M.} and Villeneuve, {M. C.} and Y. Lavall{\'e}e and Reichow, {M. K.} and Wallace, {P. A.} and Siratovich, {P. A.} and Gravley, {D. M.}",
year = "2019",
month = nov,
day = "1",
doi = "10.1029/2019GC008409",
language = "English",
volume = "20.2019",
pages = "5251--5269",
journal = "Geochemistry, geophysics, geosystems",
issn = "1525-2027",
publisher = "American Geophysical Union",
number = "11",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Increasing the Permeability of Hydrothermally Altered Andesite by Transitory Heating

AU - Mordensky, S. P.

AU - Kennedy, B. M.

AU - Villeneuve, M. C.

AU - Lavallée, Y.

AU - Reichow, M. K.

AU - Wallace, P. A.

AU - Siratovich, P. A.

AU - Gravley, D. M.

PY - 2019/11/1

Y1 - 2019/11/1

N2 - Changes in permeability can impact geological processes, geohazards, and geothermal energy production. In hydrothermal systems, high-temperature heat sources drive fluid convection through the pore network of reservoir rocks. Additionally, thermal fluctuations may induce microfracturing and affect the mineralogical stability of the reservoir rock, thus modifying the fluid pathways and affecting permeability and strength. This study describes the results of thermal heating events lasting several hours on a “moderately altered” plagioclase-clinochlore-calcite-quartz andesite and a “highly altered” plagioclase-clinozoisite-quartz-clinochlore andesite from the Rotokawa Geothermal Field, New Zealand. We use a low thermal gradient (~1.2 °C/min) in an H2O-saturated, 20-MPa pressure environment to constrain changes in petrophysical properties associated with transitory thermal phenomena between 350 and 739 °C. As the treatment temperature increases, the mass reduces, while porosity and permeability increase. These effects were greater in the “moderately altered” andesite than in the “highly altered” andesite. Microfracturing is responsible for these changes at lower temperatures (e.g., ≤400 °C). At higher temperatures (e.g., >400 °C), microfracturing remains partially responsible for these rock property changes (e.g., higher permeability); however, these changes are also a product of clinochlore, quartz, and (when present) calcite reacting out of the altered andesite, and increasing porosity. We propose that at temperatures >400 °C, volumetric phase changes associated with heat-driven reactions in a wet environment can contribute to microcracking and porosity/permeability changes. Our data support observations where high-temperature conditions at the margins of magma bodies can be associated with substantial increased permeability and decreased strength.

AB - Changes in permeability can impact geological processes, geohazards, and geothermal energy production. In hydrothermal systems, high-temperature heat sources drive fluid convection through the pore network of reservoir rocks. Additionally, thermal fluctuations may induce microfracturing and affect the mineralogical stability of the reservoir rock, thus modifying the fluid pathways and affecting permeability and strength. This study describes the results of thermal heating events lasting several hours on a “moderately altered” plagioclase-clinochlore-calcite-quartz andesite and a “highly altered” plagioclase-clinozoisite-quartz-clinochlore andesite from the Rotokawa Geothermal Field, New Zealand. We use a low thermal gradient (~1.2 °C/min) in an H2O-saturated, 20-MPa pressure environment to constrain changes in petrophysical properties associated with transitory thermal phenomena between 350 and 739 °C. As the treatment temperature increases, the mass reduces, while porosity and permeability increase. These effects were greater in the “moderately altered” andesite than in the “highly altered” andesite. Microfracturing is responsible for these changes at lower temperatures (e.g., ≤400 °C). At higher temperatures (e.g., >400 °C), microfracturing remains partially responsible for these rock property changes (e.g., higher permeability); however, these changes are also a product of clinochlore, quartz, and (when present) calcite reacting out of the altered andesite, and increasing porosity. We propose that at temperatures >400 °C, volumetric phase changes associated with heat-driven reactions in a wet environment can contribute to microcracking and porosity/permeability changes. Our data support observations where high-temperature conditions at the margins of magma bodies can be associated with substantial increased permeability and decreased strength.

KW - Altered andesite

KW - Hydrothermal alteration

KW - permeability

KW - porosity

KW - rotokawa andesite

KW - Thermal treatment

U2 - 10.1029/2019GC008409

DO - 10.1029/2019GC008409

M3 - Article

AN - SCOPUS:85075477913

VL - 20.2019

SP - 5251

EP - 5269

JO - Geochemistry, geophysics, geosystems

JF - Geochemistry, geophysics, geosystems

SN - 1525-2027

IS - 11

ER -