A Fast Alternative to Core Plug Tests for Optimising Injection Water Salinity for EOR

Hassenkam, Tue; Andersson, Martin; Hilner, Emelie; Matthiesen, J.; Dobberschütz, Sören; Dalby, Kim N.; Bovet, N.; Stipp, Susan Louise Svane; Salino, Peter; Reddick, C.; Collins, I.R.

doi:10.2118/169136-ms

Cited by 5 publications

(3 citation statements)

References 31 publications

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“…Our AFM results show that increasing pH from 7 to 11 indeed decreased 80% of the adhesion force for both functional groups, confirming that low salinity water likely lifts off oil films from pore surfaces thus increasing water-wetting. Similar results were also observed by Hassenkam et al, ,, who measured adhesion force of a model oil on sandstone grains and model rocks using AFM. Their results show that low salinity water decreases the adhesion force between the model oil and both types of rock, implying that adhesion force reduction of oil and rock surface in the presence of low salinity water can be achieved at pore surfaces in reservoirs.…”

Section: Resultssupporting

confidence: 88%

Role of Basal-Charged Clays in Low Salinity Effect in Sandstone Reservoirs: Adhesion Force on Muscovite using Atomic Force Microscope

2019

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Low salinity water flooding appears to be an important means to improved oil recovery in sandstone reservoirs. Wettability alteration has been identified as the main effect behind low salinity water flooding due to the interaction of oil− brine−rock interfaces, where clay minerals play a significant role. While how edge-charged clays (kaolinite-bearing sandstone) contribute to wettability alteration during low salinity water flooding has been well-studied, the role of basal charged clays (smectite, illite, and chlorite) in wettability alteration remains unclear. We previously confirmed that basal charged clays trigger pH increases (2 to 3) due to ion exchange with added impetus of mineral dissolution by means of geochemical modeling (Chen et al. Fuel 2018, 112−117). In this work, we hypothesized that the pH increase triggers negative zeta potential of both oil−brine and brine−clays, thus increasing double layer expansion, as well as hydrophilicity. To test our hypothesis, we measured adhesion force between functional groups (−CH 3 and −COOH) and muscovite using atomic force microscope (AFM) at pH of 7 and 11 with NaCl at a concentration of 10 000 mg/L NaCl. To gain a better isotherm thermodynamic understanding, we measured zeta potential of brine−muscovite and oil−brine and computed total disjoining pressure under constant potential condition using flat to flat and sphere to flat thermodynamic models. Zeta potential measurements show that increasing pH shifted the zeta potential of oil−brine and brine−muscovite to more negative values thus increasing the electrical double layer force. Our AFM measurements show that increasing pH from 7 to 11 indeed decreased 80% of the adhesion force for both functional groups. Total disjoining pressure calculation predicts the same trend as the AFM adhesion measurements. However, the sphere to flat thermodynamic model predicts a correct degree of decrease in adhesion force compared to AFM, implying that the sphere to flat model should be applied to interpret AFM results. Together, our results confirm that basal-charged clays can significantly contribute to low salinity effect due to electrical double layer expansion, thus expanding the application envelope of low salinity flooding in sandstone reservoirs bearing basal-charged clays.

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Section: Resultssupporting

confidence: 88%

Role of Basal-Charged Clays in Low Salinity Effect in Sandstone Reservoirs: Adhesion Force on Muscovite using Atomic Force Microscope

2019

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“…On experiments in sandstone, the low salinity response can clearly be observed using CFM on treated and fresh samples. − Hassenkam and colleagues and Matthiesen and colleagues demonstrated that overall adhesion and the low salinity response are strongly influenced by the organic materials that are naturally present on all mineral surfaces, even when they have never been in contact with oil or gas. In several experiments with the same conditions as presented in this study, the average adhesion on grains from sandstone that had been solvent treated was ∼110 pN, which is comparable to the average adhesion obtained in our study on the treated sample, i.e.…”

Section: Resultsmentioning

confidence: 99%

“…There is general agreement that divalent ions must be present in the formation water, polar components are required in the crude oil, and the presence of clay in the reservoir is essential. ,, It has not yet been established if these requirements also hold for carbonate rocks. Previous work has demonstrated the effectiveness of atomic force microscopy (AFM), in chemical force mapping (CFM) mode, for observing changes in surface wettability that result from changing the salinity of the solution in contact with mineral grains from sandstones. ,,, The experiments used AFM tips functionalized with molecules ending in methyl (−CH 3 ) to make them hydrophobic or carboxyl (−COO(H)) to make them polar, either neutral or acidic, depending on the pH of the solution. A change toward slightly more water wet pore surfaces has been suggested as one of the main causes for the low salinity response .…”

Section: Introductionmentioning

confidence: 99%

Low Salinity Effect at Pore Scale: Probing Wettability Changes in Middle East Limestone

et al. 2016

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The effectiveness of low salinity flooding for enhanced oil recovery (EOR) in sandstone reservoirs has been demonstrated in core plug and field tests as well as at molecular scale, but in carbonate reservoirs the results are mixed. With atomic force microscopy (AFM) chemical force mapping (CFM), using a methyl (CH3) functionalized tip, we tracked the wettability of limestone pore surfaces (before and after solvent treatment) during exposure to high and low salinity solutions at a submicrometer scale. The correlation between adhesion and salinity was weak for both the treated and the fresh samples, but detailed analysis of the force maps demonstrated that on the fresh limestone there are areas that clearly respond to changes in salinity. Adhesion decreased when salinity decreased on some areas, and on others adhesion increased. To understand this behavior, we analyzed the surfaces with X-ray photoelectron spectroscopy (XPS) and energy dispersive X-ray spectroscopy (EDXS). The amount of organic material on the solvent treated samples was lower than on the fresh samples, but the amount and type of organic compounds were considerably different. These differences provide a likely explanation for the differences in the effectiveness of low salinity flooding that have been reported in the literature and lead us to conclude that for the samples analyzed in our study, the response in carbonate rocks is controlled by an intricate interplay between the composition of the tightly adsorbed organic material, the minerals on which it is adsorbed, and the functional groups present in the oil. Consequently, if the effectiveness of low salinity flooding in carbonate reservoirs is to be predicted, characterization of the organic compounds in the oil and on the pore surfaces is essential.

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Mechanisms Behind LSWI/EWI Effect on Oil Recovery

Al-Shalabi

Sepehrnoori

2017

Low Salinity and Engineered Water Injection for Sandstone and Carbonate Reservoirs

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A Fast Alternative to Core Plug Tests for Optimising Injection Water Salinity for EOR

Cited by 5 publications

References 31 publications

Role of Basal-Charged Clays in Low Salinity Effect in Sandstone Reservoirs: Adhesion Force on Muscovite using Atomic Force Microscope

Role of Basal-Charged Clays in Low Salinity Effect in Sandstone Reservoirs: Adhesion Force on Muscovite using Atomic Force Microscope

Low Salinity Effect at Pore Scale: Probing Wettability Changes in Middle East Limestone

Mechanisms Behind LSWI/EWI Effect on Oil Recovery

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