Chemical Compositions in Modified Salinity Waterflooding of Calcium Carbonate Reservoirs: Experiment

Modified or low-salinity waterflooding of carbonate oil reservoirs is of considerable economic interest because of potentially inexpensive incremental oil production. The injected modified brine changes the surface chemistry of the carbonate rock and crude oil interfaces and detaches some of adhered...

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Veröffentlicht in:	Transport in porous media 2022, Vol.141 (2), p.255-278
Hauptverfasser:	Yutkin, M. P., Radke, C. J., Patzek, T. W.
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Schlagworte:	Aqueous solutions Brines Calcium carbonate Carbonate rocks Carbonates Chemical composition Civil Engineering Classical and Continuum Physics Crude oil Design Design modifications Dissolution Earth and Environmental Science Earth Sciences Enhanced oil recovery Geotechnical Engineering & Applied Earth Sciences Hydrogeology Hydrology/Water Resources Industrial Chemistry/Chemical Engineering Ion exchange Limestone Oil recovery Phase composition Reservoirs Salinity Water flooding
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description	Modified or low-salinity waterflooding of carbonate oil reservoirs is of considerable economic interest because of potentially inexpensive incremental oil production. The injected modified brine changes the surface chemistry of the carbonate rock and crude oil interfaces and detaches some of adhered crude oil. Composition design of brine modified to enhance oil recovery is determined by labor-intensive trial-and-error laboratory corefloods. Unfortunately, limestone, which predominantly consists of aqueous-reactive calcium carbonate, alters injected brine composition by mineral dissolution/precipitation. Accordingly, the rock reactivity hinders rational design of brines tailored to improve oil recovery. Previously, we presented a theoretical analysis of 1D, single-phase brine injection into calcium carbonate-rock that accounts for mineral dissolution, ion exchange, and dispersion (Yutkin et al. in SPE J 23(01):084–101, 2018. https://doi.org/10.2118/182829-PA ). Here, we present the results of single-phase waterflood-brine experiments that verify the theoretical framework. We show that concentration histories eluted from Indiana limestone cores possess features characteristic of fast calcium carbonate dissolution, 2:1 ion exchange, and high dispersion. The injected brine reaches chemical equilibrium inside the porous rock even at injection rates higher than 3.5 × 10 - 3 m s - 1 (1000 ft/day). Ion exchange results in salinity waves observed experimentally, while high dispersion is responsible for long concentration history tails. Using the verified theoretical framework, we briefly explore how these processes modify aqueous-phase composition during the injection of designer brines into a calcium-carbonate reservoir. Because of high salinity of the initial and injected brines, ion exchange affects injected concentrations only in high surface area carbonates/limestones, such as chalks. Calcium-carbonate dissolution only affects aqueous solution pH. The rock surface composition is affected by all processes.
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Previously, we presented a theoretical analysis of 1D, single-phase brine injection into calcium carbonate-rock that accounts for mineral dissolution, ion exchange, and dispersion (Yutkin et al. in SPE J 23(01):084–101, 2018. https://doi.org/10.2118/182829-PA ). Here, we present the results of single-phase waterflood-brine experiments that verify the theoretical framework. We show that concentration histories eluted from Indiana limestone cores possess features characteristic of fast calcium carbonate dissolution, 2:1 ion exchange, and high dispersion. The injected brine reaches chemical equilibrium inside the porous rock even at injection rates higher than 3.5 × 10 - 3 m s - 1 (1000 ft/day). Ion exchange results in salinity waves observed experimentally, while high dispersion is responsible for long concentration history tails. Using the verified theoretical framework, we briefly explore how these processes modify aqueous-phase composition during the injection of designer brines into a calcium-carbonate reservoir. Because of high salinity of the initial and injected brines, ion exchange affects injected concentrations only in high surface area carbonates/limestones, such as chalks. Calcium-carbonate dissolution only affects aqueous solution pH. 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P.</creatorcontrib><creatorcontrib>Radke, C. J.</creatorcontrib><creatorcontrib>Patzek, T. W.</creatorcontrib><title>Chemical Compositions in Modified Salinity Waterflooding of Calcium Carbonate Reservoirs: Experiment</title><title>Transport in porous media</title><addtitle>Transp Porous Med</addtitle><description>Modified or low-salinity waterflooding of carbonate oil reservoirs is of considerable economic interest because of potentially inexpensive incremental oil production. The injected modified brine changes the surface chemistry of the carbonate rock and crude oil interfaces and detaches some of adhered crude oil. Composition design of brine modified to enhance oil recovery is determined by labor-intensive trial-and-error laboratory corefloods. Unfortunately, limestone, which predominantly consists of aqueous-reactive calcium carbonate, alters injected brine composition by mineral dissolution/precipitation. Accordingly, the rock reactivity hinders rational design of brines tailored to improve oil recovery. Previously, we presented a theoretical analysis of 1D, single-phase brine injection into calcium carbonate-rock that accounts for mineral dissolution, ion exchange, and dispersion (Yutkin et al. in SPE J 23(01):084–101, 2018. https://doi.org/10.2118/182829-PA ). Here, we present the results of single-phase waterflood-brine experiments that verify the theoretical framework. We show that concentration histories eluted from Indiana limestone cores possess features characteristic of fast calcium carbonate dissolution, 2:1 ion exchange, and high dispersion. The injected brine reaches chemical equilibrium inside the porous rock even at injection rates higher than 3.5 × 10 - 3 m s - 1 (1000 ft/day). Ion exchange results in salinity waves observed experimentally, while high dispersion is responsible for long concentration history tails. Using the verified theoretical framework, we briefly explore how these processes modify aqueous-phase composition during the injection of designer brines into a calcium-carbonate reservoir. Because of high salinity of the initial and injected brines, ion exchange affects injected concentrations only in high surface area carbonates/limestones, such as chalks. Calcium-carbonate dissolution only affects aqueous solution pH. The rock surface composition is affected by all processes.</description><subject>Aqueous solutions</subject><subject>Brines</subject><subject>Calcium carbonate</subject><subject>Carbonate rocks</subject><subject>Carbonates</subject><subject>Chemical composition</subject><subject>Civil Engineering</subject><subject>Classical and Continuum Physics</subject><subject>Crude oil</subject><subject>Design</subject><subject>Design modifications</subject><subject>Dissolution</subject><subject>Earth and Environmental Science</subject><subject>Earth Sciences</subject><subject>Enhanced oil recovery</subject><subject>Geotechnical Engineering & Applied Earth Sciences</subject><subject>Hydrogeology</subject><subject>Hydrology/Water Resources</subject><subject>Industrial Chemistry/Chemical Engineering</subject><subject>Ion exchange</subject><subject>Limestone</subject><subject>Oil recovery</subject><subject>Phase composition</subject><subject>Reservoirs</subject><subject>Salinity</subject><subject>Water flooding</subject><issn>0169-3913</issn><issn>1573-1634</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2022</creationdate><recordtype>article</recordtype><sourceid>C6C</sourceid><sourceid>AFKRA</sourceid><sourceid>BENPR</sourceid><sourceid>CCPQU</sourceid><sourceid>DWQXO</sourceid><recordid>eNp9kE1LxDAYhIMouK7-AU8Bz9V8tWm8SfELVgRd8BjSNFmzdJOadGX33xut4M3THGaeeV8GgHOMLjFC_CphTBgpEMEFwhyXxe4AzHDJaYEryg7BDOFKFFRgegxOUlojlLGazUDXvJuN06qHTdgMIbnRBZ-g8_ApdM4608FX1Tvvxj18U6OJtg_Z8CsYLGxUr912kzW2wWcXvphk4mdwMV3D291gotsYP56CI6v6ZM5-dQ6Wd7fL5qFYPN8_NjeLQtOKjkUrmCHMCq0pt6pUuOWCIKYM6UxHVN3VtGO6rZCtEW6R4BwLZlGrNWuZIHQOLqbaIYaPrUmjXIdt9PmiJBWlJRespDlFppSOIaVorBzylyruJUbye0w5jSnzmPJnTLnLEJ2glMN-ZeJf9T_UF27beW4</recordid><startdate>2022</startdate><enddate>2022</enddate><creator>Yutkin, M. 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W.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c363t-b94e24f9cc37fa5a1b79204ae2ded2a8d83d4cb60f801b0977194f0bcc4b4923</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2022</creationdate><topic>Aqueous solutions</topic><topic>Brines</topic><topic>Calcium carbonate</topic><topic>Carbonate rocks</topic><topic>Carbonates</topic><topic>Chemical composition</topic><topic>Civil Engineering</topic><topic>Classical and Continuum Physics</topic><topic>Crude oil</topic><topic>Design</topic><topic>Design modifications</topic><topic>Dissolution</topic><topic>Earth and Environmental Science</topic><topic>Earth Sciences</topic><topic>Enhanced oil recovery</topic><topic>Geotechnical Engineering & Applied Earth Sciences</topic><topic>Hydrogeology</topic><topic>Hydrology/Water Resources</topic><topic>Industrial Chemistry/Chemical Engineering</topic><topic>Ion exchange</topic><topic>Limestone</topic><topic>Oil recovery</topic><topic>Phase composition</topic><topic>Reservoirs</topic><topic>Salinity</topic><topic>Water flooding</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Yutkin, M. 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P.</au><au>Radke, C. J.</au><au>Patzek, T. W.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Chemical Compositions in Modified Salinity Waterflooding of Calcium Carbonate Reservoirs: Experiment</atitle><jtitle>Transport in porous media</jtitle><stitle>Transp Porous Med</stitle><date>2022</date><risdate>2022</risdate><volume>141</volume><issue>2</issue><spage>255</spage><epage>278</epage><pages>255-278</pages><issn>0169-3913</issn><eissn>1573-1634</eissn><abstract>Modified or low-salinity waterflooding of carbonate oil reservoirs is of considerable economic interest because of potentially inexpensive incremental oil production. The injected modified brine changes the surface chemistry of the carbonate rock and crude oil interfaces and detaches some of adhered crude oil. Composition design of brine modified to enhance oil recovery is determined by labor-intensive trial-and-error laboratory corefloods. 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Ion exchange results in salinity waves observed experimentally, while high dispersion is responsible for long concentration history tails. Using the verified theoretical framework, we briefly explore how these processes modify aqueous-phase composition during the injection of designer brines into a calcium-carbonate reservoir. Because of high salinity of the initial and injected brines, ion exchange affects injected concentrations only in high surface area carbonates/limestones, such as chalks. Calcium-carbonate dissolution only affects aqueous solution pH. The rock surface composition is affected by all processes.</abstract><cop>Dordrecht</cop><pub>Springer Netherlands</pub><doi>10.1007/s11242-021-01715-x</doi><tpages>24</tpages><orcidid>https://orcid.org/0000-0002-9743-7107</orcidid><orcidid>https://orcid.org/0000-0002-9389-7579</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Aqueous solutions Brines Calcium carbonate Carbonate rocks Carbonates Chemical composition Civil Engineering Classical and Continuum Physics Crude oil Design Design modifications Dissolution Earth and Environmental Science Earth Sciences Enhanced oil recovery Geotechnical Engineering & Applied Earth Sciences Hydrogeology Hydrology/Water Resources Industrial Chemistry/Chemical Engineering Ion exchange Limestone Oil recovery Phase composition Reservoirs Salinity Water flooding
title	Chemical Compositions in Modified Salinity Waterflooding of Calcium Carbonate Reservoirs: Experiment
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