A New PC-SAFT Model for Pure Water, Water–Hydrocarbons, and Water–Oxygenates Systems and Subsequent Modeling of VLE, VLLE, and LLE

Ahmed, Saifuddin; Ferrando, Nicolas; Hemptinne, Jean-Charles de; Simonin, Jean‐Pierre; Bernard, Olivier; Baudouin, Olivier

doi:10.1021/acs.jced.6b00565

Cited by 35 publications

(32 citation statements)

References 63 publications

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“…Later on, this approach, with one temperature‐dependent and another temperature‐independent binary adjustable parameter, has been implemented for estimating the data in water solutions of nitrogen and hydrogen. Some additional references presenting the modeling of phase behavior in aqueous systems should be acknowledged as well. A particular importance for this research present the studies of Economou and Donohue and Economou and Tsonopoulos .…”

Section: Introductionmentioning

confidence: 99%

Predicting phase behavior in aqueous systems without fitting binary parameters II: Gases and non‐aromatic hydrocarbons

2017

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This investigation continues a series of studies evaluating the capability of the recently proposed CP‐PC‐SAFT and sPC‐SAFT of Liang et al. to estimate the thermodynamic properties of aqueous systems in the entirely predictive manner. Similarly to the previously considered systems, CP‐PC‐SAFT remains a realistic estimator of the available data on critical loci, high pressure‐high temperature phase equilibria and volumetric properties also in the cases of non‐polar gases and non‐aromatic hydrocarbons from argon and nitrogen till n‐eicosane and squalene while keeping zero values of binary parameters. Nevertheless, such application of the model poses certain unavoidable compromises on its accuracy. Inter alia, CP‐PC‐SAFT is a particularly inaccurate estimator of the water‐rich liquid phases away from the critical points. sPC‐SAFT predicts these data in a more reliable manner. Moreover, its predictive capability goes beyond the liquid phases and it exhibits a remarkable accuracy in forecasting various phase equilibria below the critical point of water. © 2017 American Institute of Chemical Engineers AIChE J, 2017

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Section: Introductionmentioning

confidence: 99%

Predicting phase behavior in aqueous systems without fitting binary parameters II: Gases and non‐aromatic hydrocarbons

2017

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“…Moreover, improvements in the current work is significant in correlating densities at low salinities and infinite dilution condition which is essential for an improved mixed solvent electrolyte model [25,68]. It can be seen that the densities of alkali halides conform fairly well at low salinities which is the capability of the model developed in our previous work [131]. The parameters for the ions that are finally used in the model are listed in table 6 (set 1).…”

Section: Correlation Results For Alkali Halide Brinesmentioning

confidence: 77%

“…Since we have seen that the model is able to describe the salting-out phenomena in alkane or acid gas + brine systems, it can now be used to study vapor-liquid equilibrium of various mixed solvent salt systems. Pure water and several pure solvents such as methanol/ethanol/1-propanol have been already parameterized in a previous work [131] and parameters are recalled in table 3. Binary mixture of methanol-water were parameterized using cross interaction parameters (‰ o , ‹ o and ' o ), here three parameter were chosen to have better accuracy in the description of binary phase equilbria (without fitting ' o , deviations were close to 10% in AADP and AADY, compared to 1.8% when including this additional correction).…”

Section: Mixed Solvent Electrolytesmentioning

confidence: 99%

Modeling of mixed-solvent electrolyte systems

Ahmed

Ferrando

Hemptinne

et al. 2018

Fluid Phase Equilibria

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Models for mixed-solvent strong electrolytes, using an equation of state (EoS) are reviewed in this work. Through the example of ePPC-SAFT (that includes a Born term and ionic association), the meaning and the effect of each contribution to the solvation energy and the mean ionic activity coefficient are investigated. The importance of the dielectric constant is critically reviewed, with a focus on the use of a salt-concentration dependent function. The parameterization is performed using two adjustable parameters for each ion: a minimum approach distance () and an association energy (). These two parameters are optimized by fitting experimental activity coefficient and liquid density data, for all alkali halide salts simultaneously, in the range 298K to 423K. The model is subsequently tested on a large number of available experimental data, including salting out of Methane/Ethane/CO 2 /H 2 S. In all cases the deviations in bubble pressures were below 20% AADP. Predictions of vapor-liquid equilibrium of mixed solvent electrolyte systems containing methanol, ethanol are also made where deviations in bubble pressures were found to be below 10% (AADP).

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“…The molecular size and energy parameters of the listed versions vary within the range 1.91-3.59[Å] for σ and 839-2,932[K] for ǫ/k B pointing again to the fact that these parameters may hardly have anything common with physical reality and are pure numbers. As an interesting example we may mention conclusions of the very recent paper by Ahmed et al [82]. They report excellent results for the VLE of water and other compounds with one interesting feature: to obtain these results, the size of the monomer unit has to swell with increasing temperature, which contradicts both common sense and the observed (and obtained by theory) behavior; with increasing temperature, the molecules attain kinetic energy and get closer to each other which means that, effectively, their excluded volume shrinks.…”

Section: Saft Equationsmentioning

confidence: 91%

“…In their paper [33], Muller and Gubbins conclude that these interactions are more important than it was previously thought and this would also fully agree with the results shown in Table 1. An extension of Equation (33) by including explicitly the dipoledipole contribution was considered by Karakatsani et al [81] to deal with strongly dipolar fluids and recently also by Ahem et al [82]. An extension along the same path was made by Liu et al [83] who, in addition to incorporating the dipole-dipole interaction, employed the hard-core Yukawa for the monomer-monomer interaction instead of the LJ.…”

Section: Van Der Waals-type Approach: Saftmentioning

confidence: 99%

On Molecular-Based Equations of State: Perturbation Theories, Simple Models, and SAFT Modeling

Nezbeda

2020

Front. Phys.

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A New PC-SAFT Model for Pure Water, Water–Hydrocarbons, and Water–Oxygenates Systems and Subsequent Modeling of VLE, VLLE, and LLE

Cited by 35 publications

References 63 publications

Predicting phase behavior in aqueous systems without fitting binary parameters II: Gases and non‐aromatic hydrocarbons

Predicting phase behavior in aqueous systems without fitting binary parameters II: Gases and non‐aromatic hydrocarbons

Modeling of mixed-solvent electrolyte systems

On Molecular-Based Equations of State: Perturbation Theories, Simple Models, and SAFT Modeling

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