2016
DOI: 10.1016/j.juogr.2016.05.004
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Altering wettability to recover more oil from tight formations

Abstract: We describe here a method for modifying the bulk composition (pH, salinity, hardness) of fracturing fluids and overflushes to modify wettability and increase oil recovery from tight formations. Oil wetting of tight formations is usually controlled by adhesion to illite, kerogen, or both; adhesion to carbonate minerals may also play a role when clays are minor. Oil-illite adhesion is sensitive to salinity, dissolved divalent cation content, and pH. We measure adhesion between middle Bakken formation oil and cor… Show more

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Cited by 36 publications
(30 citation statements)
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“…Moreover, the interaction of the asphaltene-brine-silica system is also thought to be governed by thermodynamics [26][27][28][29], which can be depicted using DLVO theory, together with electrostatics, [23,[30][31][32], which can be described using surface complexation modelling. In order to understand how the surface species at asphaltene-brine and brine-silica interfaces impact the interaction of asphaltene-brine-silica system, a geochemical study was performed in the following subsection.…”
Section: Effect Of Salinity On Interactions Of Asphaltene-brine-silicmentioning
confidence: 99%
See 1 more Smart Citation
“…Moreover, the interaction of the asphaltene-brine-silica system is also thought to be governed by thermodynamics [26][27][28][29], which can be depicted using DLVO theory, together with electrostatics, [23,[30][31][32], which can be described using surface complexation modelling. In order to understand how the surface species at asphaltene-brine and brine-silica interfaces impact the interaction of asphaltene-brine-silica system, a geochemical study was performed in the following subsection.…”
Section: Effect Of Salinity On Interactions Of Asphaltene-brine-silicmentioning
confidence: 99%
“…Asphaltene surface -NH + = -N + H + -6.0 -COOH = -COO -+ H + -5.0 Silica surface >SiOH = >SiO − + H + -4.0 [44] Note: As shown in Table 2, the "-" in -NH + or -COOH represents the groups present at the asphaltenebrine interface [23], and ">" in >SiOH represents the groups present at the silica-brine interface [30,45].…”
Section: Geochemical Reactions Log K298kmentioning
confidence: 99%
“…Given that this work aims to understand the response of non-polar component on the adhesion at calcite surface with the presence of various brines, we used model oil compound containing -CH 3 groups to represent hydrocarbon functional groups [27,38,39]. In this work, we used Octadecane (C 18 H 38 ) for contact angle measurements, and 1-Octadecanethiol (C 18 H 38 S) for AFM measurements.…”
Section: Oilmentioning
confidence: 99%
“…To better quantify and predict the wettability alteration process, surface complexation modelling has been implemented to model chemical surface species from oil and calcite surfaces, thus characterizing the adhesion of oil and calcite [22,23,[27][28][29][30]. For example, Brady et al [22] developed a surface complexation model to characterize the wettability of oil-brine-calcite using a bond product sum concept, which is equal to [ 3 Ca + ].…”
Section: Introductionmentioning
confidence: 99%
“…Shale oil reservoirs mainly consist of clays (50-70%), while a small amount of quartz, feldspar remain in reservoirs [7]. Moreover, clays comprise basal charged clays (e.g., smectite, illite, and chlorite) [19], and edge-charged clays (kaolintie) [20]. Due to the different crystal structures, basal charged clays and edge-charged clays have different surface chemistries [21].…”
Section: Mineralsmentioning
confidence: 99%