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Mineralogical and geochemical analysis of Fe-phases in drill-cores from the Triassic Stuttgart Formation at Ketzin CO2 storage site before CO2 arrival

Mineralogical and geochemical analysis of Fe-phases in drill-cores from the Triassic Stuttgart Formation at Ketzin CO2 storage site before CO2 arrival
Mineralogical and geochemical analysis of Fe-phases in drill-cores from the Triassic Stuttgart Formation at Ketzin CO2 storage site before CO2 arrival
Reactive iron (Fe) oxides and sheet silicate-bound Fe in reservoir rocks may affect the subsurface storage of CO2 through several processes by changing the capacity to buffer the acidification by CO2 and the permeability of the reservoir rock: (1) the reduction of three-valent Fe in anoxic environments can lead to an increase in pH, (2) under sulphidic conditions, Fe may drive sulphur cycling and lead to the formation of pyrite, and (3) the leaching of Fe from sheet silicates may affect silicate diagenesis. In order to evaluate the importance of Fe-reduction on the CO2 reservoir, we analysed the Fe geochemistry in drill-cores from the Triassic Stuttgart Formation (Schilfsandstein) recovered from the monitoring well at the CO2 test injection site near Ketzin, Germany. The reservoir rock is a porous, poorly to moderately cohesive fluvial sandstone containing up to 2–4 wt% reactive Fe. Based on a sequential extraction, most Fe falls into the dithionite-extractable Fe-fraction and Fe bound to sheet silicates, whereby some Fe in the dithionite-extractable Fe-fraction may have been leached from illite and smectite. Illite and smectite were detected in core samples by X-ray diffraction and confirmed as the main Fe-containing mineral phases by X-ray absorption spectroscopy. Chlorite is also present, but likely does not contribute much to the high amount of Fe in the silicate-bound fraction. The organic carbon content of the reservoir rock is extremely low (<0.3 wt%), thus likely limiting microbial Fe-reduction or sulphate reduction despite relatively high concentrations of reactive Fe-mineral phases in the reservoir rock and sulphate in the reservoir fluid. Both processes could, however, be fuelled by organic matter that is mobilized by the flow of supercritical CO2 or introduced with the drilling fluid. Over long time periods, a potential way of liberating additional reactive Fe could occur through weathering of silicates due to acidification by CO2.
1866-6280
Kasina, Monika
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Bock, Susanne
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Würdemann, Hilke
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Pudlo, Dieter
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Picard, Aude
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Lichtschlag, Anna
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März, Christian
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Wagenknecht, Laura
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Wehrmann, Laura M.
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Vogt, Christoph
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Meister, Patrick
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Kasina, Monika
c4f08707-ea8c-4533-81bf-275a075ed280
Bock, Susanne
cb725571-b81b-41b8-a4cd-792229c374ee
Würdemann, Hilke
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Pudlo, Dieter
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Picard, Aude
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Lichtschlag, Anna
be1568d9-cc63-4f85-bd38-a93dfd7e245f
März, Christian
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Wagenknecht, Laura
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Wehrmann, Laura M.
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Vogt, Christoph
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Meister, Patrick
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Kasina, Monika, Bock, Susanne, Würdemann, Hilke, Pudlo, Dieter, Picard, Aude, Lichtschlag, Anna, März, Christian, Wagenknecht, Laura, Wehrmann, Laura M., Vogt, Christoph and Meister, Patrick (2017) Mineralogical and geochemical analysis of Fe-phases in drill-cores from the Triassic Stuttgart Formation at Ketzin CO2 storage site before CO2 arrival. Environmental Earth Sciences, 76 (4), [161]. (doi:10.1007/s12665-017-6460-9).

Record type: Article

Abstract

Reactive iron (Fe) oxides and sheet silicate-bound Fe in reservoir rocks may affect the subsurface storage of CO2 through several processes by changing the capacity to buffer the acidification by CO2 and the permeability of the reservoir rock: (1) the reduction of three-valent Fe in anoxic environments can lead to an increase in pH, (2) under sulphidic conditions, Fe may drive sulphur cycling and lead to the formation of pyrite, and (3) the leaching of Fe from sheet silicates may affect silicate diagenesis. In order to evaluate the importance of Fe-reduction on the CO2 reservoir, we analysed the Fe geochemistry in drill-cores from the Triassic Stuttgart Formation (Schilfsandstein) recovered from the monitoring well at the CO2 test injection site near Ketzin, Germany. The reservoir rock is a porous, poorly to moderately cohesive fluvial sandstone containing up to 2–4 wt% reactive Fe. Based on a sequential extraction, most Fe falls into the dithionite-extractable Fe-fraction and Fe bound to sheet silicates, whereby some Fe in the dithionite-extractable Fe-fraction may have been leached from illite and smectite. Illite and smectite were detected in core samples by X-ray diffraction and confirmed as the main Fe-containing mineral phases by X-ray absorption spectroscopy. Chlorite is also present, but likely does not contribute much to the high amount of Fe in the silicate-bound fraction. The organic carbon content of the reservoir rock is extremely low (<0.3 wt%), thus likely limiting microbial Fe-reduction or sulphate reduction despite relatively high concentrations of reactive Fe-mineral phases in the reservoir rock and sulphate in the reservoir fluid. Both processes could, however, be fuelled by organic matter that is mobilized by the flow of supercritical CO2 or introduced with the drilling fluid. Over long time periods, a potential way of liberating additional reactive Fe could occur through weathering of silicates due to acidification by CO2.

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Accepted/In Press date: 1 February 2017
e-pub ahead of print date: 16 February 2017
Published date: 16 February 2017
Organisations: Marine Geoscience, National Oceanography Centre

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Local EPrints ID: 406823
URI: http://eprints.soton.ac.uk/id/eprint/406823
ISSN: 1866-6280
PURE UUID: c28c39d2-de2a-4c2e-8286-a7fa33fb1557

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Date deposited: 23 Mar 2017 02:04
Last modified: 15 Mar 2024 12:42

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Contributors

Author: Monika Kasina
Author: Susanne Bock
Author: Hilke Würdemann
Author: Dieter Pudlo
Author: Aude Picard
Author: Anna Lichtschlag
Author: Christian März
Author: Laura Wagenknecht
Author: Laura M. Wehrmann
Author: Christoph Vogt
Author: Patrick Meister

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