Large-scale CO2 storage — Is it feasible?
CCS is generally estimated to have to account for about 20% of the reduction of CO2 emissions to the atmosphere. This paper focuses on the technical aspects of CO2 storage, even if the CCS challenge is equally dependent upon finding viable international solutions to a wide range of economic, politic...
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EDP Sciences
2013
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| Online Access: | https://doi.org/10.1051/epjconf/20135401004 https://doaj.org/article/187e19f23d95451bba1a3fce76413502 |
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ftdoajarticles:oai:doaj.org/article:187e19f23d95451bba1a3fce76413502 2023-05-15T18:20:13+02:00 Large-scale CO2 storage — Is it feasible? Johansen H. 2013-06-01T00:00:00Z https://doi.org/10.1051/epjconf/20135401004 https://doaj.org/article/187e19f23d95451bba1a3fce76413502 EN eng EDP Sciences http://dx.doi.org/10.1051/epjconf/20135401004 https://doaj.org/toc/2100-014X doi:10.1051/epjconf/20135401004 2100-014X https://doaj.org/article/187e19f23d95451bba1a3fce76413502 EPJ Web of Conferences, Vol 54, p 01004 (2013) Physics QC1-999 article 2013 ftdoajarticles https://doi.org/10.1051/epjconf/20135401004 2022-12-31T16:15:35Z CCS is generally estimated to have to account for about 20% of the reduction of CO2 emissions to the atmosphere. This paper focuses on the technical aspects of CO2 storage, even if the CCS challenge is equally dependent upon finding viable international solutions to a wide range of economic, political and cultural issues. It has already been demonstrated that it is technically possible to store adequate amounts of CO2 in the subsurface (Sleipner, InSalah, Snøhvit). The large-scale storage challenge (several Gigatons of CO2 per year) is more an issue of minimizing cost without compromising safety, and of making international regulations.The storage challenge may be split into 4 main parts: 1) finding reservoirs with adequate storage capacity, 2) make sure that the sealing capacity above the reservoir is sufficient, 3) build the infrastructure for transport, drilling and injection, and 4) set up and perform the necessary monitoring activities. More than 150 years of worldwide experience from the production of oil and gas is an important source of competence for CO2 storage. The storage challenge is however different in three important aspects: 1) the storage activity results in pressure increase in the subsurface, 2) there is no production of fluids that give important feedback on reservoir performance, and 3) the monitoring requirement will have to extend for a much longer time into the future than what is needed during oil and gas production. An important property of CO2 is that its behaviour in the subsurface is significantly different from that of oil and gas. CO2 in contact with water is reactive and corrosive, and may impose great damage on both man-made and natural materials, if proper precautions are not executed. On the other hand, the long-term effect of most of these reactions is that a large amount of CO2 will become immobilized and permanently stored as solid carbonate minerals. The reduced opportunity for direct monitoring of fluid samples close to the reservoir, the general pressure build up, and ... Article in Journal/Newspaper Snøhvit Directory of Open Access Journals: DOAJ Articles Sleipner ENVELOPE(-41.417,-41.417,63.883,63.883) EPJ Web of Conferences 54 01004 |
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English |
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Physics QC1-999 |
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Physics QC1-999 Johansen H. Large-scale CO2 storage — Is it feasible? |
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Physics QC1-999 |
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CCS is generally estimated to have to account for about 20% of the reduction of CO2 emissions to the atmosphere. This paper focuses on the technical aspects of CO2 storage, even if the CCS challenge is equally dependent upon finding viable international solutions to a wide range of economic, political and cultural issues. It has already been demonstrated that it is technically possible to store adequate amounts of CO2 in the subsurface (Sleipner, InSalah, Snøhvit). The large-scale storage challenge (several Gigatons of CO2 per year) is more an issue of minimizing cost without compromising safety, and of making international regulations.The storage challenge may be split into 4 main parts: 1) finding reservoirs with adequate storage capacity, 2) make sure that the sealing capacity above the reservoir is sufficient, 3) build the infrastructure for transport, drilling and injection, and 4) set up and perform the necessary monitoring activities. More than 150 years of worldwide experience from the production of oil and gas is an important source of competence for CO2 storage. The storage challenge is however different in three important aspects: 1) the storage activity results in pressure increase in the subsurface, 2) there is no production of fluids that give important feedback on reservoir performance, and 3) the monitoring requirement will have to extend for a much longer time into the future than what is needed during oil and gas production. An important property of CO2 is that its behaviour in the subsurface is significantly different from that of oil and gas. CO2 in contact with water is reactive and corrosive, and may impose great damage on both man-made and natural materials, if proper precautions are not executed. On the other hand, the long-term effect of most of these reactions is that a large amount of CO2 will become immobilized and permanently stored as solid carbonate minerals. The reduced opportunity for direct monitoring of fluid samples close to the reservoir, the general pressure build up, and ... |
| format |
Article in Journal/Newspaper |
| author |
Johansen H. |
| author_facet |
Johansen H. |
| author_sort |
Johansen H. |
| title |
Large-scale CO2 storage — Is it feasible? |
| title_short |
Large-scale CO2 storage — Is it feasible? |
| title_full |
Large-scale CO2 storage — Is it feasible? |
| title_fullStr |
Large-scale CO2 storage — Is it feasible? |
| title_full_unstemmed |
Large-scale CO2 storage — Is it feasible? |
| title_sort |
large-scale co2 storage — is it feasible? |
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EDP Sciences |
| publishDate |
2013 |
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https://doi.org/10.1051/epjconf/20135401004 https://doaj.org/article/187e19f23d95451bba1a3fce76413502 |
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ENVELOPE(-41.417,-41.417,63.883,63.883) |
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Sleipner |
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Sleipner |
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Snøhvit |
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Snøhvit |
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EPJ Web of Conferences, Vol 54, p 01004 (2013) |
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http://dx.doi.org/10.1051/epjconf/20135401004 https://doaj.org/toc/2100-014X doi:10.1051/epjconf/20135401004 2100-014X https://doaj.org/article/187e19f23d95451bba1a3fce76413502 |
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