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dc.contributor.authorDillen, Menno
dc.contributor.authorLindeberg, Erik Gøsta Brun
dc.contributor.authorAagaard, Per
dc.contributor.authorAker, Eyvind
dc.contributor.authorSæther, Ola Magne
dc.contributor.authorJohansen, Harald
dc.contributor.authorLien, Martha
dc.contributor.authorHatzignatiou, Dimitrios Georgios
dc.contributor.authorGolmen, Lars Gunder
dc.contributor.authorHellevang, Jon Oddvar
dc.date.accessioned2016-11-03T10:15:17Z
dc.date.accessioned2016-11-10T11:51:20Z
dc.date.available2016-11-03T10:15:17Z
dc.date.available2016-11-10T11:51:20Z
dc.date.issued2009
dc.identifier.citationEnergy Procedia 2009, 1(1):2397-2404nb_NO
dc.identifier.issn1876-6102
dc.identifier.urihttp://hdl.handle.net/11250/2420452
dc.description-nb_NO
dc.description.abstractThe long-term safety of future CO2 storage projects in aquifers will not only rely on a comprehensive geological characterisation of the formation and capillary seal, but also on the ability to effectively monitor the underground migration of CO2 to allow immediate and effective remediation to prevent CO2 from escaping to the atmosphere in case of leakage. To achieve such effective remediation it is necessary that deep-probing monitoring tools can detect any leakage at an early stage long before CO2 has reached the surface. It will also be necessary to conduct shallow monitoring, at the perimeter of the storage system, where leakage to the atmosphere or ocean is imminent. Field-scale experimental observations have been designed and planned to study the sensitivity of various existing monitoring systems as a mean of monitoring CO2 leakage. Two onshore geological formations in Norway have been identified as suitable for systematic studies of detection limits for monitoring technologies in a wellcontrolled geological environment. One of the sites consists of Quaternary unconsolidated sand with a high porosity and permeability, allowing fast CO2 plume rise and the possibility of creating chimney-like plumes. The other site is a low-permeable Permian consolidated sandstone, where viscous forces will be stronger during the injection phase, thus permitting more variations in the plume shape depending on the injection rate. At both selected sites, small amounts of CO2 will be injected into the geological formations, which have no seal that will prevent the CO2 upward migration through the underground strata. The CO2 plumes will therefore mimic a potential leakage from an actual storage site and, by frequently repeating monitoring measurements, the performance of different methods will be tested. These monitoring measurements will include geophysical, down-hole, ecological/environmental, chemical/geochemical, atmospheric, and satellite methods. The results of the project will illustrate the performance of different monitoring technologies and provide reference for further developments of the methods, if needed. Various research organisations from United Kingdom, France and Norway will participate in the design and implementation of this project along with the project’s industrial partners.nb_NO
dc.language.isoengnb_NO
dc.rightsNavngivelse-Ikkekommersiell-DelPåSammeVilkår 3.0 Norge*
dc.rights.urihttp://creativecommons.org/licenses/by-nc-sa/3.0/no/*
dc.titleA field laboratory for monitoring CO2 leakagenb_NO
dc.typeJournal articlenb_NO
dc.typePeer reviewednb_NO
dc.date.updated2016-11-03T10:15:17Z
dc.source.journalEnergy Procedianb_NO
dc.identifier.doi10.1016/j.egypro.2009.01.312
dc.identifier.cristin917562


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Navngivelse-Ikkekommersiell-DelPåSammeVilkår 3.0 Norge
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