Theoretical and experimental investigation of effect of salinity and asphaltene on IFT of brine and live oil samples

Soleymanzadeh, Aboozar; Rahmati, Ahmad; Yousefi, Mohammad; Roshani, Babak

doi:10.1007/s13202-020-01020-1

Cited by 17 publications

(8 citation statements)

References 42 publications

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“…The oil/brine IFT was lower than the oil/deionized water IFT. This behavior is consistent with many previous studies, in which the oil/brine IFT was significantly affected by brine composition, salinity, and oil composition. − The result shows that increasing the FM concentration caused a slight reduction in IFT. The 30 wt % FM solutions at different initial pH values, 6.1 and 7.0, had similar IFT values but resulted in markedly different oil recoveries (Figure ).…”

Section: Resultssupporting

confidence: 92%

Geochemical Impact of High-Concentration Formate Solution Injection on Rock Wettability for Enhanced Oil Recovery and Geologic Carbon Storage

Oyenowo,

Wang,

Mirzaei-Paiaman

et al. 2024

Energy Fuels

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This paper presents new data on core-scale wettability alteration of carbonate porous media with FM concentrations up to 30 wt % in NaCl brine. Experimental data from Amott tests, core floods, calcite dissolution experiments, and zeta potential measurements were analyzed to mechanistically understand the wettability alteration observed in the experiments. Static calcite dissolution tests showed that the degree of dissolution increased with increasing FM concentration in NaCl brine, even with an initially neutral pH. For example, the calcium concentration in the 30 wt % FM solution was 15.9 times greater than that in the NaCl brine with an initial pH of 7.0. Furthermore, reducing the initial solution pH from 7.0 to 6.1 for the 30 wt % FM solution caused the calcium ion concentration to increase by a factor of 3.2. Geochemical modeling and Raman analysis indicated that increased calcite dissolution was caused by interactions between calcium and FM ions. The 30 wt % FM solution with an initial pH of 6.1 yielded 4.7 times greater oil recovery than the NaCl brine in the spontaneous imbibition. The resulting Amott index indicated the wettability alteration to a water-wet state by the FM solution. The 30 wt % FM solution with an initial pH of 7.0 yielded only 30% greater oil recovery than the brine in the spontaneous imbibition; however, it reached nearly the same total oil recovery (spontaneous and forced) as the 30 wt % FM solution with an initial pH of 6.1. A numerical model was calibrated using core flood data, based on which the relative permeabilities indicated the core-scale wettability alteration by FM solutions. Results showed that increasing the FM concentration in the injection brine rendered the initially oil-wet core to a more water-wet state and that the in situ solution pH played an important role in wettability alteration by FM solution in carbonate media.

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Section: Resultssupporting

confidence: 92%

Geochemical Impact of High-Concentration Formate Solution Injection on Rock Wettability for Enhanced Oil Recovery and Geologic Carbon Storage

Oyenowo,

Wang,

Mirzaei-Paiaman

et al. 2024

Energy Fuels

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“…Better IFT reduction was achieved with the use of TA-2 surfactant in brines of varied salinities than TA-3 surfactant. Reduction in IFT with increase in brine salinity was observed with the use of TA-2, while increase in IFT with increase in salinity was observed with TA-3 indicating that there is a relationship between brine salinity and interfacial tension of the oleic-aqueous system, and it is dependent on the type of salt, amount of salt, type, and concentration of surfactant present [37]. This further showed the tolerance and efficiency of TA-2 surfactant in saline environments.…”

Section: Interfacial Tension Measurementsmentioning

confidence: 92%

Evaluation of modified cashew nutshell liquid as natural surfactants for chemical flooding in sandstone oil reservoirs

2022

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Bio-based oilfield chemicals are gaining attention due to their availability, cost-effectiveness, and non-toxic nature. Surfactants facilitate recovery of residual oil by reducing the interfacial tension between two immiscible fluids. Cashew nutshell liquid (CNSL) extracted from Anacardium occidentale waste shells was modified using triethanolamine and evaluated as a natural alternative to traditional surfactants. Phase behavior analysis, interfacial tension, critical micelle concentration (CMC) measurements, and core flooding analysis were performed to ascertain the compatibility and recoverability of the cashew nutshell liquid derivatives on sandstone reservoirs. Interfacial tension was reduced from 10.46 to 1.66 mN/m at CMC of 1 g/L. Additional recovery factor and displacement efficiency of 12% OOIP and 32.5%, respectively, was achieved at laboratory temperature. The effect of temperature on residual oil recovery was determined by subjecting the oil displacement experiment to reservoir temperature of 80˚C, resulting in recovery factor and displacement efficiency of 9% OOIP and 25%, respectively.

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“…Interfacial tension (IFT) is usually used as the intensity criteria of fluid–fluid interactions and as one of the dominant mechanisms for EOR in low-salinity waterflooding, as reported by Mokhtari et al., , Tetteh et al, − and Farhadi et al However, due to the experimental differences, some controversial conclusions have been proposed. For ion amount, Ikeda et al, Barati-Harooni et al, and Soleymanzadeh et al reported that an increase in salinity resulted in an increase in IFT. Correspondingly, Okasha and Alshiwaish and Yousef et al observed a general trend of IFT decreases with decreasing salinity.…”

Section: Introductionmentioning

confidence: 99%

Effects and Mechanisms of Acidic Crude Oil–Aqueous Solution Interaction in Low-Salinity Waterflooding

Chai

Liu

et al. 2021

Energy Fuels

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Crude oil−aqueous solution interactions play an important role in low-salinity waterflooding, but their effects and mechanisms have not been well clarified. Core flooding experiments were first conducted to analyze the effects of crude oil− aqueous solution interactions on enhanced oil recovery (EOR). Then, interfacial tension (IFT) and interfacial dilatational rheology (IDR), total organic carbon (TOC), and ζ-potential measurements were combined to investigate the mechanisms of crude oil− aqueous solution interactions in low-salinity waterflooding. Core flooding results showed that crude oil−aqueous solution interactions are important in low-salinity waterflooding and that adjusting the ionic composition of the aqueous solution could affect EOR. Herein, Mg 2+ and Ca 2+ both had positive effects on EOR, while SO 4 2− showed no positive effect. The IFT and IDR, TOC, and ζ-potential results indicated that the ionic composition of aqueous solutions has a great influence on crude oil−aqueous solution interactions. Thereof, Mg 2+ , Ca 2+ , and Na + preferentially interact with acidic polar molecules and enhance crude oil−aqueous solution interactions, and the intensity is Mg 2+ > Ca 2+ > Na + . SO 4 2− interacts with cations and acidic polar molecules simultaneously, consequently reducing the effects of cations on crude oil−aqueous solution interactions in varying degrees. Therefore, the positive effects of Ca 2+ and Mg 2+ exceed the negative influence of SO 4 2− in CaSO 4 and MgSO 4 , while the negative impact of SO 4 2− outweighs the positive effect of Na + in Na 2 SO 4 .

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Theoretical and experimental investigation of effect of salinity and asphaltene on IFT of brine and live oil samples

Cited by 17 publications

References 42 publications

Geochemical Impact of High-Concentration Formate Solution Injection on Rock Wettability for Enhanced Oil Recovery and Geologic Carbon Storage

Geochemical Impact of High-Concentration Formate Solution Injection on Rock Wettability for Enhanced Oil Recovery and Geologic Carbon Storage

Evaluation of modified cashew nutshell liquid as natural surfactants for chemical flooding in sandstone oil reservoirs

Effects and Mechanisms of Acidic Crude Oil–Aqueous Solution Interaction in Low-Salinity Waterflooding

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