CHAPTER 1 History of Low-Salinity and Smart Waterflood  13

                2
          and SO 4  to adjust the charge density of chalk surface  measurement, contact angle measurement, coreflood-
          by the adherence of potential-determining ions on the  ing, and NMR tests. The IFT measurements are carried
          surface modifies wettability of chalk. In addition,  out using live oil and the various brines at the reservoir

          Mg 2þ  with SO 4 2   has a high affinity on the chalk sur-  temperature with 212 F. The dilution of seawater
          face, and the affinity increases in high temperature con-  slightly decreases the IFT, but the reduction of IFT is
          dition. Based on these conclusions, this study proposed  less than 2 dyne/cm. There is a relatively higher reduc-
          the different mechanisms for the wettability alteration  tion of IFT when the brine is changed from connate
          induced by seawater in low and high temperatures,  water to seawater. Though the IFT changes from 40 to
          respectively.                                 33 dyne/cm, the reduction changing fluid/fluid interac-
            The upstream research team from Saudi Aramco has  tion is not enough to modify wettability. In the contact
          initiated a research program called “SmartWater Flood”  angle measurements, contact angles are monitored over
          to explore the IOR/EOR from carbonates by modifying  a period of 2 days. The contact angle for twice-diluted
          the brine composition. The research team reported  seawater changes from 90 degrees to 80 degrees. When
          the comprehensive results of laboratory studies to  the twice-diluted seawater is switched to 10-times-
          investigate the impact of salinity and ionic composition  diluted seawater, the contact angle between the brine
          in COBR system. In the study (Yousef, Al-Saleh,  and crude oil changes from 80 degrees to 69 degrees.
          Al-Kaabi, & Al-Jawfi, 2011), the carbonate cores, which  For 20-times- and 100-times-diluted seawaters, there
          is composed of 80% calcite, 13% dolomite, 6% anhy-  is no more reduction of contact angle. These results
          drite, and less than 1% quartz, are subject to the exper-  demonstrate the potential of wettability modification
          iments. The field connate water with 213,734 ppm TDS  toward water-wetness when seawater is diluted by fac-
          and seawater with 57,670 ppm TDS are used in these  tors of 0.5 and 0.1. These observations lead to the two
          experiments. To quantify the impact of ionic composi-  sets of coreflood tests injecting various diluted seawa-
          tion, the various diluted seawaters by factors of 0.5,  ters into connate water-saturated cores. The secondary
          0.1, 0.05, and 0.01 are exploited in the comprehensive  recovery of seawater and tertiary recovery of the various
          experiments. The seawater has more than 10 times  diluted seawaters are deployed into cores. Fig. 1.15
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          higher concentration of SO 4  over the connate water.  illustrates the oil recovery of the first coreflooding

          Crude oil has 30 API and total acid number (TAN) with  experiment. The seawater injection for secondary recov-
          0.25 mg KOH/g oil. This study conducted the IFT  ery produces 67% of OOIP. In tertiary mode, the



























                FIG. 1.15 History of oil recovery and injection rate for the first coreflood experiment. (Credit: From Yousef, A.
                A., Al-Saleh, S. H., Al-Kaabi, A., & Al-Jawfi, M. S. (2011). Laboratory investigation of the impact of injection-
                water salinity and ionic content on oil recovery from carbonate reservoirs. SPE Reservoir Evaluation and
                Engineering, 14(5), 578e593. https://doi.org/10.2118/137634-PA.)