A combined experimental and modelling study of granite hydrothermal alteration

•Granite hydrothermal alteration was investigated at 180 °C and at 2 ≤ pH ≤ 8.5.•Kinetic modelling provides satisfactory account of studied geochemical reactions.•Al-phases precipitation rates and surface area evolution to be better estimated.•Experimental quantification will enhance reactive transp...

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Veröffentlicht in:	Geothermics 2023-02, Vol.108, p.102633, Article 102633
Hauptverfasser:	Saldi, Giuseppe D., Knauss, Kevin G., Spycher, Nicolas, Oelkers, Eric H., Jones, Adrian P.
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Sprache:	eng
Schlagworte:	Dissolution rates Geochemical modelling Geothermal systems Granite hydrothermal alteration Kinetics Mineral precipitation Sciences of the Universe
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creator	Saldi, Giuseppe D. Knauss, Kevin G. Spycher, Nicolas Oelkers, Eric H. Jones, Adrian P.
description	•Granite hydrothermal alteration was investigated at 180 °C and at 2 ≤ pH ≤ 8.5.•Kinetic modelling provides satisfactory account of studied geochemical reactions.•Al-phases precipitation rates and surface area evolution to be better estimated.•Experimental quantification will enhance reactive transport model performance. Geochemical reactions can induce significant changes of rock reservoir porosity and permeability via mineral dissolution and precipitation processes, affecting the long-term fluid behaviour within various geological systems. The understanding and quantification of these reactions rely on field and experimental studies and on the predictions of reactive transport models. The present study was aimed at assessing the extent to which current geochemical models integrating available mineral dissolution/precipitation rate equations can reproduce the experimental data obtained from 4 to 17-day long hydrothermal alteration experiments of a muscovite-biotite granite and, thus, help provide an accurate description of the evolution of geothermal systems within granitic reservoirs. The experiments were conducted at a constant temperature of 180 °C and over an aqueous fluid pH range of 2 to 8.5, using both mixed-flow and static batch reactors. Modelled major element (K, Al, Si, Ca, and Mg) concentrations were generally in satisfactory agreement with the corresponding measured elemental fluxes – the differences between modelled and experimental values were generally within a factor of 5 – and the predicted identity and mass of formed secondary phases were consistent with the microscopic observations of the reacted solids. However, larger differences between measured and modelled element concentrations were observed when significant amounts of secondary phases formed, notably at pH 2 to 3, and for longer-term batch experiments. Much of this concentration difference stems from the underestimation of the amounts of Al-phases formed at acid to near-neutral pH. Although an idealized rock composition was considered, the observed mismatch between model calculations and experimental data can be attributed to inadequate mineral precipitation reaction rates and a poor description of reactive surface areas in existing geochemical modelling codes. More accurate quantification of precipitation kinetics, including nucleation and growth, and improved descriptions of the temporal change of mineral surface area would enhance the predictive capabilities of reactive trans
doi_str_mv	10.1016/j.geothermics.2022.102633
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Geochemical reactions can induce significant changes of rock reservoir porosity and permeability via mineral dissolution and precipitation processes, affecting the long-term fluid behaviour within various geological systems. The understanding and quantification of these reactions rely on field and experimental studies and on the predictions of reactive transport models. The present study was aimed at assessing the extent to which current geochemical models integrating available mineral dissolution/precipitation rate equations can reproduce the experimental data obtained from 4 to 17-day long hydrothermal alteration experiments of a muscovite-biotite granite and, thus, help provide an accurate description of the evolution of geothermal systems within granitic reservoirs. The experiments were conducted at a constant temperature of 180 °C and over an aqueous fluid pH range of 2 to 8.5, using both mixed-flow and static batch reactors. Modelled major element (K, Al, Si, Ca, and Mg) concentrations were generally in satisfactory agreement with the corresponding measured elemental fluxes – the differences between modelled and experimental values were generally within a factor of 5 – and the predicted identity and mass of formed secondary phases were consistent with the microscopic observations of the reacted solids. However, larger differences between measured and modelled element concentrations were observed when significant amounts of secondary phases formed, notably at pH 2 to 3, and for longer-term batch experiments. Much of this concentration difference stems from the underestimation of the amounts of Al-phases formed at acid to near-neutral pH. Although an idealized rock composition was considered, the observed mismatch between model calculations and experimental data can be attributed to inadequate mineral precipitation reaction rates and a poor description of reactive surface areas in existing geochemical modelling codes. 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Geochemical reactions can induce significant changes of rock reservoir porosity and permeability via mineral dissolution and precipitation processes, affecting the long-term fluid behaviour within various geological systems. The understanding and quantification of these reactions rely on field and experimental studies and on the predictions of reactive transport models. The present study was aimed at assessing the extent to which current geochemical models integrating available mineral dissolution/precipitation rate equations can reproduce the experimental data obtained from 4 to 17-day long hydrothermal alteration experiments of a muscovite-biotite granite and, thus, help provide an accurate description of the evolution of geothermal systems within granitic reservoirs. The experiments were conducted at a constant temperature of 180 °C and over an aqueous fluid pH range of 2 to 8.5, using both mixed-flow and static batch reactors. Modelled major element (K, Al, Si, Ca, and Mg) concentrations were generally in satisfactory agreement with the corresponding measured elemental fluxes – the differences between modelled and experimental values were generally within a factor of 5 – and the predicted identity and mass of formed secondary phases were consistent with the microscopic observations of the reacted solids. However, larger differences between measured and modelled element concentrations were observed when significant amounts of secondary phases formed, notably at pH 2 to 3, and for longer-term batch experiments. Much of this concentration difference stems from the underestimation of the amounts of Al-phases formed at acid to near-neutral pH. Although an idealized rock composition was considered, the observed mismatch between model calculations and experimental data can be attributed to inadequate mineral precipitation reaction rates and a poor description of reactive surface areas in existing geochemical modelling codes. More accurate quantification of precipitation kinetics, including nucleation and growth, and improved descriptions of the temporal change of mineral surface area would enhance the predictive capabilities of reactive transport models and benefit, particularly, the efforts aimed at increasing the sustainability of EGS reservoirs.</description><subject>Dissolution rates</subject><subject>Geochemical modelling</subject><subject>Geothermal systems</subject><subject>Granite hydrothermal alteration</subject><subject>Kinetics</subject><subject>Mineral precipitation</subject><subject>Sciences of the Universe</subject><issn>0375-6505</issn><issn>1879-3576</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2023</creationdate><recordtype>article</recordtype><recordid>eNqNkE9LAzEQxYMoWKvfIV6Frfmzye4eS1ErFL3oOWSTSZuyTUqyLfbbu2VFPHoaGN57M--H0D0lM0qofNzO1hD7DaSdN3nGCGPDnknOL9CE1lVTcFHJSzQhvBKFFERco5uct4SQSlRkgt7m2MRd6wNYDF97SH4Hodcd1sHiXbTQdT6sce4P9oSjw-ukg-8Bb042jXfP2q6HpHsfwy26crrLcPczp-jz-eljsSxW7y-vi_mq0CUnfdEao1vHnNaa05oBcNq6umxLYoiohNHOUe7qlouybqzTtRFVKW0jGGNOyopP0cOYu9Gd2g9P63RSUXu1nK-UD_mgSEmbuhTySAdxM4pNijkncL8OStSZotqqPxTVmaIaKQ7exeiFoc3RQ1LZeAgGrE9gemWj_0fKN44xgsw</recordid><startdate>20230201</startdate><enddate>20230201</enddate><creator>Saldi, Giuseppe D.</creator><creator>Knauss, Kevin G.</creator><creator>Spycher, Nicolas</creator><creator>Oelkers, Eric H.</creator><creator>Jones, Adrian P.</creator><general>Elsevier Ltd</general><general>Elsevier</general><scope>AAYXX</scope><scope>CITATION</scope><scope>1XC</scope><orcidid>https://orcid.org/0000-0003-3885-8187</orcidid><orcidid>https://orcid.org/0000-0003-1292-5521</orcidid></search><sort><creationdate>20230201</creationdate><title>A combined experimental and modelling study of granite hydrothermal alteration</title><author>Saldi, Giuseppe D. ; Knauss, Kevin G. ; Spycher, Nicolas ; Oelkers, Eric H. ; Jones, Adrian P.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a430t-bccabf2faaa3182ee31bf84b40c0575caff13f8b35489dfa8c5746d95222f6673</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2023</creationdate><topic>Dissolution rates</topic><topic>Geochemical modelling</topic><topic>Geothermal systems</topic><topic>Granite hydrothermal alteration</topic><topic>Kinetics</topic><topic>Mineral precipitation</topic><topic>Sciences of the Universe</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Saldi, Giuseppe D.</creatorcontrib><creatorcontrib>Knauss, Kevin G.</creatorcontrib><creatorcontrib>Spycher, Nicolas</creatorcontrib><creatorcontrib>Oelkers, Eric H.</creatorcontrib><creatorcontrib>Jones, Adrian P.</creatorcontrib><collection>CrossRef</collection><collection>Hyper Article en Ligne (HAL)</collection><jtitle>Geothermics</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Saldi, Giuseppe D.</au><au>Knauss, Kevin G.</au><au>Spycher, Nicolas</au><au>Oelkers, Eric H.</au><au>Jones, Adrian P.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>A combined experimental and modelling study of granite hydrothermal alteration</atitle><jtitle>Geothermics</jtitle><date>2023-02-01</date><risdate>2023</risdate><volume>108</volume><spage>102633</spage><pages>102633-</pages><artnum>102633</artnum><issn>0375-6505</issn><eissn>1879-3576</eissn><abstract>•Granite hydrothermal alteration was investigated at 180 °C and at 2 ≤ pH ≤ 8.5.•Kinetic modelling provides satisfactory account of studied geochemical reactions.•Al-phases precipitation rates and surface area evolution to be better estimated.•Experimental quantification will enhance reactive transport model performance. Geochemical reactions can induce significant changes of rock reservoir porosity and permeability via mineral dissolution and precipitation processes, affecting the long-term fluid behaviour within various geological systems. The understanding and quantification of these reactions rely on field and experimental studies and on the predictions of reactive transport models. The present study was aimed at assessing the extent to which current geochemical models integrating available mineral dissolution/precipitation rate equations can reproduce the experimental data obtained from 4 to 17-day long hydrothermal alteration experiments of a muscovite-biotite granite and, thus, help provide an accurate description of the evolution of geothermal systems within granitic reservoirs. The experiments were conducted at a constant temperature of 180 °C and over an aqueous fluid pH range of 2 to 8.5, using both mixed-flow and static batch reactors. Modelled major element (K, Al, Si, Ca, and Mg) concentrations were generally in satisfactory agreement with the corresponding measured elemental fluxes – the differences between modelled and experimental values were generally within a factor of 5 – and the predicted identity and mass of formed secondary phases were consistent with the microscopic observations of the reacted solids. However, larger differences between measured and modelled element concentrations were observed when significant amounts of secondary phases formed, notably at pH 2 to 3, and for longer-term batch experiments. Much of this concentration difference stems from the underestimation of the amounts of Al-phases formed at acid to near-neutral pH. Although an idealized rock composition was considered, the observed mismatch between model calculations and experimental data can be attributed to inadequate mineral precipitation reaction rates and a poor description of reactive surface areas in existing geochemical modelling codes. More accurate quantification of precipitation kinetics, including nucleation and growth, and improved descriptions of the temporal change of mineral surface area would enhance the predictive capabilities of reactive transport models and benefit, particularly, the efforts aimed at increasing the sustainability of EGS reservoirs.</abstract><pub>Elsevier Ltd</pub><doi>10.1016/j.geothermics.2022.102633</doi><orcidid>https://orcid.org/0000-0003-3885-8187</orcidid><orcidid>https://orcid.org/0000-0003-1292-5521</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Dissolution rates Geochemical modelling Geothermal systems Granite hydrothermal alteration Kinetics Mineral precipitation Sciences of the Universe
title	A combined experimental and modelling study of granite hydrothermal alteration
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