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Theoretical Modeling of the Impact of Salt Precipitation on CO(2) Storage Potential in Fractured Saline Reservoirs

[Image: see text] Deep saline reservoirs have the capacity to hold large volumes of CO(2). However, apart from the high brine salinity, which poses an injectivity challenge, a high percentage of saline reservoirs are also fractured. The mechanisms of drying and salt precipitation and the resulting i...

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Autores principales: Sokama-Neuyam, Yen A., Boakye, Patrick, Aggrey, Wilberforce N., Obeng, Nicholas O., Adu-Boahene, Francis, Woo, Seung Han, Ursin, Jann Rune
Formato: Online Artículo Texto
Lenguaje:English
Publicado: American Chemical Society 2020
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7315589/
https://www.ncbi.nlm.nih.gov/pubmed/32596615
http://dx.doi.org/10.1021/acsomega.0c01687
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author Sokama-Neuyam, Yen A.
Boakye, Patrick
Aggrey, Wilberforce N.
Obeng, Nicholas O.
Adu-Boahene, Francis
Woo, Seung Han
Ursin, Jann Rune
author_facet Sokama-Neuyam, Yen A.
Boakye, Patrick
Aggrey, Wilberforce N.
Obeng, Nicholas O.
Adu-Boahene, Francis
Woo, Seung Han
Ursin, Jann Rune
author_sort Sokama-Neuyam, Yen A.
collection PubMed
description [Image: see text] Deep saline reservoirs have the capacity to hold large volumes of CO(2). However, apart from the high brine salinity, which poses an injectivity challenge, a high percentage of saline reservoirs are also fractured. The mechanisms of drying and salt precipitation and the resulting impact on CO(2) injection are unique in fractured reservoirs. Analytical models were developed to investigate the impact of salt precipitation on CO(2) injectivity and storage capacity. Two types of fractured saline reservoirs were considered: type I fractured reservoirs, where storage capacity and injectivity are contributed by only fractures, and type II fractured reservoirs, where both fractures and the adjacent rock matrix blocks contribute to CO(2) storage and injectivity. We found that, depending on the initial brine salinity, salt precipitation could severely impair CO(2) injectivity and reduce storage capacity. Salt precipitation had a fourfold impact on CO(2) injectivity compared to storage capacity. Type I reservoirs with high irreducible brine saturation were less susceptible to salt clogging in the fractures. The results also suggest that fractures with rectangular aperture were less likely to be plugged by salt compared to elliptical fractures. Contrary to previous reports, some fractured deep saline reservoirs may not be suitable for CO(2) storage. Generally, type II fractured reservoirs were found to be more suitable for CO(2) storage in terms of susceptibility to salt clogging. The findings provide valuable understanding of the mechanisms and effect of drying and salt precipitation on CO(2) storage potential, making a strong case for CO(2) storage in naturally fractured deep saline reservoirs.
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spelling pubmed-73155892020-06-26 Theoretical Modeling of the Impact of Salt Precipitation on CO(2) Storage Potential in Fractured Saline Reservoirs Sokama-Neuyam, Yen A. Boakye, Patrick Aggrey, Wilberforce N. Obeng, Nicholas O. Adu-Boahene, Francis Woo, Seung Han Ursin, Jann Rune ACS Omega [Image: see text] Deep saline reservoirs have the capacity to hold large volumes of CO(2). However, apart from the high brine salinity, which poses an injectivity challenge, a high percentage of saline reservoirs are also fractured. The mechanisms of drying and salt precipitation and the resulting impact on CO(2) injection are unique in fractured reservoirs. Analytical models were developed to investigate the impact of salt precipitation on CO(2) injectivity and storage capacity. Two types of fractured saline reservoirs were considered: type I fractured reservoirs, where storage capacity and injectivity are contributed by only fractures, and type II fractured reservoirs, where both fractures and the adjacent rock matrix blocks contribute to CO(2) storage and injectivity. We found that, depending on the initial brine salinity, salt precipitation could severely impair CO(2) injectivity and reduce storage capacity. Salt precipitation had a fourfold impact on CO(2) injectivity compared to storage capacity. Type I reservoirs with high irreducible brine saturation were less susceptible to salt clogging in the fractures. The results also suggest that fractures with rectangular aperture were less likely to be plugged by salt compared to elliptical fractures. Contrary to previous reports, some fractured deep saline reservoirs may not be suitable for CO(2) storage. Generally, type II fractured reservoirs were found to be more suitable for CO(2) storage in terms of susceptibility to salt clogging. The findings provide valuable understanding of the mechanisms and effect of drying and salt precipitation on CO(2) storage potential, making a strong case for CO(2) storage in naturally fractured deep saline reservoirs. American Chemical Society 2020-06-15 /pmc/articles/PMC7315589/ /pubmed/32596615 http://dx.doi.org/10.1021/acsomega.0c01687 Text en Copyright © 2020 American Chemical Society This is an open access article published under an ACS AuthorChoice License (http://pubs.acs.org/page/policy/authorchoice_termsofuse.html) , which permits copying and redistribution of the article or any adaptations for non-commercial purposes.
spellingShingle Sokama-Neuyam, Yen A.
Boakye, Patrick
Aggrey, Wilberforce N.
Obeng, Nicholas O.
Adu-Boahene, Francis
Woo, Seung Han
Ursin, Jann Rune
Theoretical Modeling of the Impact of Salt Precipitation on CO(2) Storage Potential in Fractured Saline Reservoirs
title Theoretical Modeling of the Impact of Salt Precipitation on CO(2) Storage Potential in Fractured Saline Reservoirs
title_full Theoretical Modeling of the Impact of Salt Precipitation on CO(2) Storage Potential in Fractured Saline Reservoirs
title_fullStr Theoretical Modeling of the Impact of Salt Precipitation on CO(2) Storage Potential in Fractured Saline Reservoirs
title_full_unstemmed Theoretical Modeling of the Impact of Salt Precipitation on CO(2) Storage Potential in Fractured Saline Reservoirs
title_short Theoretical Modeling of the Impact of Salt Precipitation on CO(2) Storage Potential in Fractured Saline Reservoirs
title_sort theoretical modeling of the impact of salt precipitation on co(2) storage potential in fractured saline reservoirs
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7315589/
https://www.ncbi.nlm.nih.gov/pubmed/32596615
http://dx.doi.org/10.1021/acsomega.0c01687
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