Effects of Paraffinic Group on Interfacial Tension Behavior of CO<sub>2</sub>–Asphaltenic Crude Oil Systems

Mahdavi, Ehsan; Zebarjad, Fatemeh Sadat; Taghikhani, Vahid; Ayatollahi, Shahab

doi:10.1021/je500369e

Cited by 22 publications

(25 citation statements)

References 39 publications

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“…For example, the CH 4 -dominated HCs pre-saturated live light oil-CO 2 system was found to have a higher IFT/MMP, whereas the intermediate HCs pre-saturated one has a lower IFT/MMP in comparison with that of the dead light oil-CO 2 system. 18 Similar results were also found in terms of the effect of injection gas composition on the IFT/MMP studies. 15 Moreover, the effect of feed ratio of injection gas to oil on the measured IFT/MMP cannot be ignored although there is no general consensus on it.…”

Section: Introductionsupporting

confidence: 74%

“…This is because the addition of CH 4 -dominated produced gas into oil sample reduces the CO 2 solubility in the oil phase. 18 Two respective MMPs are determined to be 11.6 and 26.5 MPa from the DIM at T ¼ 53.0 and 116.1 C, both of which are slightly lower than 13.7 and 29.7 MPa of the Pembina live oil-pure CO 2 system at the same temperature. The effects of initial oil composition on the determined MMPs are further summarized in Fig.…”

Section: Temperature Effectmentioning

confidence: 87%

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Exploring the effects of four important factors on oil–CO₂ interfacial properties and miscibility in nanopores

Zhang

Jia

2017

RSC Adv.

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In this paper, a modified Peng-Robinson equation of state (PR-EOS) coupled with the parachor model and a newly-developed diminishing interface method (DIM) are applied to predict the interfacial properties and minimum miscibility pressures (MMPs) of light oil-CO 2 systems in nanopores. First, the modified PR-EOS is used to calculate the vapour-liquid equilibrium by considering the effects of capillary pressure and shifts of critical temperature and pressure. Second, a thermodynamic formula of the interfacial thickness (IT) between two mutually soluble phases is derived, based on which the novel DIM is developed. The MMP is determined by extrapolating the derivative of the IT with respect to the pressure (vd/vP) T to zero. It is found that at the pore radius of 10 nm, all three quantities, the interfacial tensions (IFTs), ITs, and MMPs, show obvious increases with temperature. The effects of the initial oil composition on the three quantities are measurable but marginal and the MMP is more sensitive to the initial oil composition at a higher temperature. Moreover, the IFTs and ITs are weakly dependent but the determined MMPs are strongly dependent on the injection gas composition. The presence of CH 4 in the injection gas results in a substantial MMP increase in nanopores. At a constant temperature, the effects of the feed ratio of injection gas to oil on the IFTs, ITs, and MMPs are negligible with pure CO 2 injection, especially at low feed gas-oil ratios (less than 0.50 : 0.50 in mole fraction), whereas they become much stronger and cause the MMPs with impure CO 2 (0.65CO 2 + 0.35CH 4 ) injection to be considerably increased from 26.3 to 40.0 MPa by reducing the feed gas-oil ratio from 0.90 : 0.10 to 0.10 : 0.90 in mole fraction.

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Section: Introductionsupporting

confidence: 74%

Section: Temperature Effectmentioning

confidence: 87%

Exploring the effects of four important factors on oil–CO₂ interfacial properties and miscibility in nanopores

Zhang

Jia

2017

RSC Adv.

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“…Solubility of components of the crude oil in CO 2 is crucial to the recovery rate. It has been found that light alkanes (C 3-10 ) compared with heavier alkanes were recovered faster and more from the crude oil phase because of their better solubility in CO 2 (Cao & Gu, 2013;Rudyk, Spirov, & Sogaard, 2013); in addition, IFT between light alkanes and CO 2 are lower than those between the heavy alkanes and CO 2 (Mahdavi, Zebarjad, Taghikhani, & Ayatollahi, 2014a). In the extraction fields, a high extraction rate of a compound largely depends on its good solubility in CO 2 .…”

Section: Introductionmentioning

confidence: 99%

“…According to Luo, Zhang, Wang, and Huang (2012), solubility of n-hexane in CO 2 is as high as 6.18 mol % at 328 K, 8.95 MPa. Using a mixed solvent (CO 2 with alkanes, light petroleum, or alcohols) instead of pure CO 2 is a common way to increase the solubility (Catchpole, Grey, & Noermark, 1998;Mahdavi, Zebarjad, Taghikhani, & Ayatollahi, 2014b;Zolghadr, Escrochi, & Ayatollahi, 2013). De Lucas, Gracia, Rincon, and García (2007) studied the solubility of squalene, orange roughy, spiny dogfish, and cod liver oil in scCO 2 , finding that the solubility was obviously improved by the addition of ethanol, 7.75% of ethanol resulted in an improvement in the solubility of cod liver oil from 4.81 to 9.07 g kg −1 at 333 K, 20 MPa.…”

Section: Introductionmentioning

confidence: 99%

Structural Effects of Nonionic Surfactants on Their Ability to Reduce the Dissolution Pressures of Heavy Hydrocarbons in Supercritical CO₂

Shi

Cheng

Liu³

et al. 2018

J Surfact & Detergents

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The effects of selected nonionic surfactants on dissolution pressures of the octacosane and hydrocarbon mixtures in supercritical CO2 (scCO2) were investigated at 318–343 K to study relationships between the structures of the surfactants and their ability to improve solubility. Dissolution pressures of the solutes were experimentally observed to be decreased by at most 11.10% and at least 0.44% in the presence of the surfactants. However, this solubility‐improving performance was diminished with an increase in the molecular chain length of the surfactant. Linear surfactants gave better solubility‐improving performances in the octacosane/scCO2 systems, while branched compounds were better in the hydrocarbon mixture/scCO2 systems, which are attributed to the similarity of the chain length between the surfactant and the solute. X‐ray computed tomography tests provided evidence for direct material exchange between the hydrocarbon mixture and scCO2.

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“…Ethoxylated fatty acid methyl esters are new biodegradable surfactants that easily hydrolyze to nontoxic and non-surface active components in sewage systems [24][25][26][27]. Compared to ethoxylated alcohols, they have better properties, lower aquatic toxicity and higher biodegradability [27,28].…”

Section: Introductionmentioning

confidence: 99%

Interfacial Tensions of Ethoxylated Fatty Acid Methyl Ester Solutions Against Crude Oil

Liu

Fang

Jin

et al. 2017

J Surfact & Detergents

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The dynamic interfacial tension (IFT) of ethoxylated fatty acid methyl ester solutions against n‐alkanes, kerosene, and diluted heavy oil have been investigated by spinning drop interfacial tensiometry. The influences of ethylene oxide (EO) groups and alkyl chain length on IFT were investigated. The experiment results show that the water solubility decreases with an increase in alkyl chain length or a decrease in EO groups. The ability to lower the interfacial tension against hydrocarbons improves with both increasing alkyl chain length and EO group at the best hydrophilic‐lipophilic balance, which can be attributed to the enhancement of the interfacial hydrophobic interactions and the rearrangement of interfacial surfactant molecules. The mixed adsorption of surfactant molecules and surface‐active components may reduce IFT to a lower value. C18=E3 shows the best synergism with surface‐active components. However, the IFT values against pure crude oil are obviously higher than those against hydrocarbons, which may be caused by the nature of heavy oil.

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Effects of Paraffinic Group on Interfacial Tension Behavior of CO₂–Asphaltenic Crude Oil Systems

Cited by 22 publications

References 39 publications

Exploring the effects of four important factors on oil–CO₂ interfacial properties and miscibility in nanopores

Exploring the effects of four important factors on oil–CO₂ interfacial properties and miscibility in nanopores

Structural Effects of Nonionic Surfactants on Their Ability to Reduce the Dissolution Pressures of Heavy Hydrocarbons in Supercritical CO₂

Interfacial Tensions of Ethoxylated Fatty Acid Methyl Ester Solutions Against Crude Oil

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Effects of Paraffinic Group on Interfacial Tension Behavior of CO2–Asphaltenic Crude Oil Systems

Cited by 22 publications

References 39 publications

Exploring the effects of four important factors on oil–CO2 interfacial properties and miscibility in nanopores

Exploring the effects of four important factors on oil–CO2 interfacial properties and miscibility in nanopores

Structural Effects of Nonionic Surfactants on Their Ability to Reduce the Dissolution Pressures of Heavy Hydrocarbons in Supercritical CO2

Interfacial Tensions of Ethoxylated Fatty Acid Methyl Ester Solutions Against Crude Oil

Contact Info

Product

Resources

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Effects of Paraffinic Group on Interfacial Tension Behavior of CO₂–Asphaltenic Crude Oil Systems

Exploring the effects of four important factors on oil–CO₂ interfacial properties and miscibility in nanopores

Exploring the effects of four important factors on oil–CO₂ interfacial properties and miscibility in nanopores

Structural Effects of Nonionic Surfactants on Their Ability to Reduce the Dissolution Pressures of Heavy Hydrocarbons in Supercritical CO₂