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Carbon mineralization in fractured mafic and ultramafic rocks: a review

Carbon mineralization in fractured mafic and ultramafic rocks: a review
Carbon mineralization in fractured mafic and ultramafic rocks: a review
Mineral carbon storage in mafic and ultramafic rock masses has the potential to be an effective and permanent mechanism to reduce anthropogenic CO2. Several successful pilot‐scale projects have been carried out in basaltic rock (e.g., CarbFix, Wallula), demonstrating the potential for rapid CO2 sequestration. However, these tests have been limited to the injection of small quantities of CO2. Thus, the longevity and feasibility of long‐term, large‐scale mineralization operations to store the levels of CO2 needed to address the present climate crisis is unknown. Moreover, CO2 mineralization in ultramafic rocks, which tend to be more reactive but less permeable, has not yet been quantified. In these systems, fractures are expected to play a crucial role in the flow and reaction of CO2 within the rock mass and will influence the CO2 storage potential of the system. Therefore, consideration of fractures is imperative to the prediction of CO2 mineralization at a specific storage site. In this review, we highlight key takeaways, successes, and shortcomings of CO2 mineralization pilot tests that have been completed and are currently underway. Laboratory experiments, directed toward understanding the complex geochemical and geomechanical reactions that occur during CO2 mineralization in fractures, are also discussed. Experimental studies and their applicability to field sites are limited in time and scale. Many modeling techniques can be applied to bridge these limitations. We highlight current modeling advances and their potential applications for predicting CO2 mineralization in mafic and ultramafic rocks.
8755-1209
Nisbet, H.
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Buscarnera, G.
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Carey, J.W.
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Chen, M.A.
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Detournay, E.
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Huang, H.
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Hyman, J.D.
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Kang, P.K.
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Kang, Q.
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Labuz, J.F.
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Li, W.
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Matter, J.
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Neil, C.W.
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Srinivasan, G.
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Sweeney, M.R.
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Voller, V.R.
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Yang, W.
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Viswanathan, H.S.
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Nisbet, H.
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Buscarnera, G.
7f3b0efd-919a-4dce-8f09-a2a87e952a9b
Carey, J.W.
6df39a5b-5349-4e77-9176-11db0734d910
Chen, M.A.
10adb125-9285-458f-a593-344cb11daa9e
Detournay, E.
f6ed43f9-fe63-4744-973d-a4cae0f199f0
Huang, H.
644a1c3e-0900-492e-9865-095a3b490354
Hyman, J.D.
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Kang, P.K.
6e7eb2eb-8271-42f8-80b5-c599746d8334
Kang, Q.
e4f5d760-8f6c-499a-aa64-9faa47a55580
Labuz, J.F.
3806b38f-371b-4867-a384-c8d706418581
Li, W.
a4bea9e8-263c-45b8-a832-055285c89c4b
Matter, J.
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Neil, C.W.
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Srinivasan, G.
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Sweeney, M.R.
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Voller, V.R.
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Yang, W.
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Viswanathan, H.S.
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Nisbet, H., Buscarnera, G., Carey, J.W., Chen, M.A., Detournay, E., Huang, H., Hyman, J.D., Kang, P.K., Kang, Q., Labuz, J.F., Li, W., Matter, J., Neil, C.W., Srinivasan, G., Sweeney, M.R., Voller, V.R., Yang, W. and Viswanathan, H.S. (2024) Carbon mineralization in fractured mafic and ultramafic rocks: a review. Reviews of Geophysics, 62 (4), [e2023RG000815]. (doi:10.1029/2023RG000815).

Record type: Article

Abstract

Mineral carbon storage in mafic and ultramafic rock masses has the potential to be an effective and permanent mechanism to reduce anthropogenic CO2. Several successful pilot‐scale projects have been carried out in basaltic rock (e.g., CarbFix, Wallula), demonstrating the potential for rapid CO2 sequestration. However, these tests have been limited to the injection of small quantities of CO2. Thus, the longevity and feasibility of long‐term, large‐scale mineralization operations to store the levels of CO2 needed to address the present climate crisis is unknown. Moreover, CO2 mineralization in ultramafic rocks, which tend to be more reactive but less permeable, has not yet been quantified. In these systems, fractures are expected to play a crucial role in the flow and reaction of CO2 within the rock mass and will influence the CO2 storage potential of the system. Therefore, consideration of fractures is imperative to the prediction of CO2 mineralization at a specific storage site. In this review, we highlight key takeaways, successes, and shortcomings of CO2 mineralization pilot tests that have been completed and are currently underway. Laboratory experiments, directed toward understanding the complex geochemical and geomechanical reactions that occur during CO2 mineralization in fractures, are also discussed. Experimental studies and their applicability to field sites are limited in time and scale. Many modeling techniques can be applied to bridge these limitations. We highlight current modeling advances and their potential applications for predicting CO2 mineralization in mafic and ultramafic rocks.

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Reviews of Geophysics - 2024 - Nisbet - Carbon Mineralization in Fractured Mafic and Ultramafic Rocks A Review - Version of Record
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Accepted/In Press date: 21 October 2024
Published date: 17 November 2024
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Identifiers

Local EPrints ID: 504680
URI: http://eprints.soton.ac.uk/id/eprint/504680
DOI: doi:10.1029/2023RG000815
ISSN: 8755-1209
PURE UUID: f90baa58-26c9-4335-bca5-9b0132ccc664
ORCID for J. Matter: ORCID iD orcid.org/0000-0002-1070-7371

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Date deposited: 17 Sep 2025 16:56
Last modified: 18 Sep 2025 01:46

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Contributors

Author: H. Nisbet
Author: G. Buscarnera
Author: J.W. Carey
Author: M.A. Chen
Author: E. Detournay
Author: H. Huang
Author: J.D. Hyman
Author: P.K. Kang
Author: Q. Kang
Author: J.F. Labuz
Author: W. Li
Author: J. Matter ORCID iD
Author: C.W. Neil
Author: G. Srinivasan
Author: M.R. Sweeney
Author: V.R. Voller
Author: W. Yang
Author: H.S. Viswanathan

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