Atmospheric densities and interfacial tensions for 1-alkanol (1-butanol to 1-octanol)+water and ether (MTBE, ETBE, DIPE, TAME and THP)+water demixed mixtures

Cartes, Marcela; Mejı́a, Andrés

doi:10.1016/j.fluid.2015.03.040

Cited by 35 publications

(31 citation statements)

References 32 publications

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“…Moreover, saturated alkanes such as n-hexane and n-heptane also have interfacial tensions as 51.1 mN/m at 293.15 K and 50.2 at 298.15 K 1 , respectively. Also, Frietes et al27 have predicted the value of methylcyclohexane as 50.8 mN/m at 293.15 K while Apostoluk and Drzymala22 have predicted the value equal to 49.61 mN/m. As methylcyclohexane has only negligible solubility with water therefore the initial interfacial tension measured in this work may be regarded as the interfacial tension between the mutually saturated phases and should be a part of the interfacial tension database.…”

mentioning

confidence: 99%

Initial Interfacial Tension for Various Organic–Water Systems and Study of the Effect of Solute Concentration and Temperature

Shahid

Usman

Akram³

et al. 2017

J. Chem. Eng. Data

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Interfacial tension is an important thermophysical property for the operations involving multi fluid-phases such as liquid-liquid extraction. This work aims at presenting a rapid experimental method and initial interfacial tension data of 10 organic compounds and water binary systems. The organic compounds include n-butyl acetate, cyclohexanol, cyclohexanone, diethyl ether, ethyl acetate, methyl ethyl ketone, methylcyclohexane, 1-octanol, and toluene. The effect of temperature on the initial interfacial tension has also been studied. These systems are chosen to cover a wide range of interfacial tension (1-51 mN/m). Comparisons between the data sets from this work and those from the literature, whenever available, show generally very good agreement. This work also presents new data of initial interfacial tension for several ternary systems with 4 organic compounds and water with varying quantities of propionic acid (0 to 0.25 mass fraction) at ambient conditions; the organic compounds include n-butyl acetate, cyclohexanone, 1-octanol, and toluene. The results show that the impact of propionic acid concentration as solute in water is large, especially at the higher solute concentrations. The initial and final (mutually saturated phases) interfacial tensions are found in agreement for different immiscible binary systems studied in this work. The method presented may be used as a rapid way of finding interfacial tensions.

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confidence: 99%

Initial Interfacial Tension for Various Organic–Water Systems and Study of the Effect of Solute Concentration and Temperature

Shahid

Usman

Akram³

et al. 2017

J. Chem. Eng. Data

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“…In order to determine the interfacial tension, the spinning drop technique [118,120] was used for different mixtures of polyethylene glycol (PEG) and magnesium sulfate. Specifically, the spinning drop tensiometer technique allows for measuring the interfacial tension between two liquid phases by analyzing the dimensions of a drop in a rotating capillary by the Vonnegut method [124,125], and is a precise and simple measurement to determine extremely low interfacial tensions. Interfacial tension values for the ATPS samples of PEG1000 / MgSO4 / H2O at several mass proportions have been found to range from 0.1 to 1 mN/m, and the density difference between the two phases vary between 30 to 60 g/cm 3 at the temperature of 22 °C.…”

Section: Choice Of Liquid Pairsmentioning

confidence: 99%

Porosimetric membrane characterization techniques: A review

Tanis-Kanbur

Peinador

Calvo

et al. 2021

Journal of Membrane Science

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“…Such a theoretical framework, which permits the calculation of the interfacial tension related to the LLE was established twenty years ago [7]. The basic idea of this approach is the applica-tion of the density gradient theory, originally developed by Van der Waals [8] and rediscovered by Cahn-Hilliard [9], to incompressible fluids, where the Helmholtz energy can be replaced by the Gibbs energy and consequently the thermodynamic properties can be modelled with a g E model rather than an equation of state [10,11] The method was used for different binary [12][13][14][15][16][17][18][19][20][21], ternary [14,21,[22][23][24][25][26] and quaternary mixtures [21,[27][28][29]. Recently, also the time-dependency of the interfacial tension caused by diffusion [14,16,24,27] or caused by a chemical reactions [21,29] were studied.…”

Section: Introductionmentioning

confidence: 99%

“…For the system under study only binary data belonging to the binary subsystems were measured , , . LLE data for the binary subsystems water + 1‐hexanol , , as well as for the binary subsystem water + hexylacetate , are available, this holds true also for interfacial tension data regarding the subsystems water + 1‐hexanol , , , and water + hexylacetate . Considering the ternary system water + 1‐hexanol + hexylacetate no experimental data, to the best of our knowledge, exists in open literature, regarding the LLE, as well as interfacial tension data at T = 298.15 K. Therefore, some experimental data with respect to the LLE and with respect to the interfacial tension were produced in order to verify or falsify the predictions.…”

Section: Introductionmentioning

confidence: 99%

“…For this propose a similar mixture is chosen, where the middle‐polar component 1‐butanol is replaced by 1‐hexanol having a lower polarity and to the same time the non‐polar component benzene is replaced by hexylacetate having a slightly higher polarity. For the system under study only binary data belonging to the binary subsystems were measured , , . LLE data for the binary subsystems water + 1‐hexanol , , as well as for the binary subsystem water + hexylacetate , are available, this holds true also for interfacial tension data regarding the subsystems water + 1‐hexanol , , , and water + hexylacetate .…”

Section: Introductionmentioning

confidence: 99%

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Liquid‐Liquid Equilibrium and Interfacial Properties of the System Water + Hexylacetate + 1‐Hexanol

Danzer

Enders

2019

Chemie Ingenieur Technik

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Experimental and theoretical investigations of the phase diagram and the interfacial tension are presented. The theoretical framework was able to predict the phase behavior and the interfacial tension with a high accuracy, where only binary experimental data enter the model parameter. The theory permits the calculation of the concentration profiles across the interface. The profiles show that 1‐hexanol will be enriched, which was expected. In same circumstances a competition between hexylacetate and 1‐hexanol was figured out leading to slight minima in the profile of 1‐hexanol.

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Atmospheric densities and interfacial tensions for 1-alkanol (1-butanol to 1-octanol)+water and ether (MTBE, ETBE, DIPE, TAME and THP)+water demixed mixtures

Cited by 35 publications

References 32 publications

Initial Interfacial Tension for Various Organic–Water Systems and Study of the Effect of Solute Concentration and Temperature

Initial Interfacial Tension for Various Organic–Water Systems and Study of the Effect of Solute Concentration and Temperature

Porosimetric membrane characterization techniques: A review

Liquid‐Liquid Equilibrium and Interfacial Properties of the System Water + Hexylacetate + 1‐Hexanol

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