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Sediment acidification and temperature increase in an artificial CO2 vent

Sediment acidification and temperature increase in an artificial CO2 vent
Sediment acidification and temperature increase in an artificial CO2 vent
We investigated the effect of an artificial CO2 vent (0.0015−0.037 mol s−1), simulating a leak from a reservoir for carbon capture and storage (CCS), on the sediment geochemistry. CO2 was injected 3 m deep into the seafloor at 120 m depth. With increasing mass flow an increasing number of vents were observed, distributed over an area of approximately 3 m. In situ profiling with microsensors for pH, T, O2 and ORP showed the geochemical effects are localized in a small area around the vents and highly variable. In measurements remote from the vent, the pH reached a value of 7.6 at a depth of 0.06 m. In a CO2 venting channel, pH reduced to below 5. Steep temperature profiles were indicative of a heat source inside the sediment. Elevated total alkalinity and Ca2+ levels showed calcite dissolution. Venting decreased sulfate reduction rates, but not aerobic respiration. A transport-reaction model confirmed that a large fraction of the injected CO2 is transported laterally into the sediment and that the reactions between CO2 and sediment generate enough heat to elevate the temperature significantly. A CO2 leak will have only local consequences for sediment biogeochemistry, and only a small fraction of the escaped CO2 will reach the sediment surface.
CO vents, Calcite dissolution, In situ measurements, Silicate weathering, Vent modelling
1750-5836
de Beer, Dirk
cb8d8130-86eb-4ecb-9496-41543e1fe536
Lichtschlag, Anna
be1568d9-cc63-4f85-bd38-a93dfd7e245f
Flohr, Anita
1e293a22-bdba-408e-9608-fed8b65e4e79
van Erk, Marit Rianne
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Ahmerkamp, Soeren
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Holtappels, Moritz
cbfb5d6a-39bf-4116-a37f-a466869a4b13
Haeckel, Matthias
eaf3aed1-1dbf-4841-ac90-2abf6012fb86
Strong, James
24e373ae-984c-4fa7-86dd-993f4fd9f48e
de Beer, Dirk
cb8d8130-86eb-4ecb-9496-41543e1fe536
Lichtschlag, Anna
be1568d9-cc63-4f85-bd38-a93dfd7e245f
Flohr, Anita
1e293a22-bdba-408e-9608-fed8b65e4e79
van Erk, Marit Rianne
eb6ade09-d417-4178-9b0b-f9f4d348f755
Ahmerkamp, Soeren
5936a264-28e0-4efa-a649-69015b624fe5
Holtappels, Moritz
cbfb5d6a-39bf-4116-a37f-a466869a4b13
Haeckel, Matthias
eaf3aed1-1dbf-4841-ac90-2abf6012fb86
Strong, James
24e373ae-984c-4fa7-86dd-993f4fd9f48e

de Beer, Dirk, Lichtschlag, Anna, Flohr, Anita, van Erk, Marit Rianne, Ahmerkamp, Soeren, Holtappels, Moritz, Haeckel, Matthias and Strong, James (2021) Sediment acidification and temperature increase in an artificial CO2 vent. International Journal of Greenhouse Gas Control, 105, [103244]. (doi:10.1016/j.ijggc.2020.103244).

Record type: Article

Abstract

We investigated the effect of an artificial CO2 vent (0.0015−0.037 mol s−1), simulating a leak from a reservoir for carbon capture and storage (CCS), on the sediment geochemistry. CO2 was injected 3 m deep into the seafloor at 120 m depth. With increasing mass flow an increasing number of vents were observed, distributed over an area of approximately 3 m. In situ profiling with microsensors for pH, T, O2 and ORP showed the geochemical effects are localized in a small area around the vents and highly variable. In measurements remote from the vent, the pH reached a value of 7.6 at a depth of 0.06 m. In a CO2 venting channel, pH reduced to below 5. Steep temperature profiles were indicative of a heat source inside the sediment. Elevated total alkalinity and Ca2+ levels showed calcite dissolution. Venting decreased sulfate reduction rates, but not aerobic respiration. A transport-reaction model confirmed that a large fraction of the injected CO2 is transported laterally into the sediment and that the reactions between CO2 and sediment generate enough heat to elevate the temperature significantly. A CO2 leak will have only local consequences for sediment biogeochemistry, and only a small fraction of the escaped CO2 will reach the sediment surface.

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Accepted/In Press date: 25 November 2020
e-pub ahead of print date: 31 December 2020
Published date: February 2021
Additional Information: Funding Information: We thank the crew of the RSS James Cook for the perfect support during the cruise. We thank Carla Sands and Doug Connelly for the constructive coordination. We are thankful for discussions with and help from Tim Ferdelman. This project has received funding from the European Union’s Horizon 2020 research and innovation program under grant agreement No. 654462 STEMM-CCS. Funding Information: We thank the crew of the RSS James Cook for the perfect support during the cruise. We thank Carla Sands and Doug Connelly for the constructive coordination. We are thankful for discussions with and help from Tim Ferdelman. This project has received funding from the European Union's Horizon 2020 research and innovation program under grant agreement No. 654462 STEMM-CCS. Publisher Copyright: © 2020
Keywords: CO vents, Calcite dissolution, In situ measurements, Silicate weathering, Vent modelling

Identifiers

Local EPrints ID: 453390
URI: http://eprints.soton.ac.uk/id/eprint/453390
ISSN: 1750-5836
PURE UUID: 704f69ed-de44-4bab-a2c9-93bba93b0c73
ORCID for Anita Flohr: ORCID iD orcid.org/0000-0002-5018-5379

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Date deposited: 13 Jan 2022 18:19
Last modified: 05 Jun 2024 17:19

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Contributors

Author: Dirk de Beer
Author: Anna Lichtschlag
Author: Anita Flohr ORCID iD
Author: Marit Rianne van Erk
Author: Soeren Ahmerkamp
Author: Moritz Holtappels
Author: Matthias Haeckel
Author: James Strong

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