Simulation Study of the Link between Molecular Association and Reentrant Miscibility for a Mixture of Molecules with Directional Interactions

Davies, Lowri A.; Jackson, George; Rull, Luis F.

doi:10.1103/physrevlett.82.5285

Cited by 25 publications

(18 citation statements)

References 54 publications

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“…Phase diagram exponents β ≃ 1/3 for the three-dimensional Ising universality class [44] are observed for both critical points (see Appendix C for details on the critical temperatures and exponents). Similar result has been reported in a previous work [12]. In our simulations, the magnitude of the quadrupole moment |Q| is an important parameter which controls the phase behavior.…”

Section: Results and Discussion For Gemc Simulationssupporting

confidence: 91%

“…Hence, understanding molecular details of the behavior of liquids with the anisotropic interactions is one of the central issues of materials science. Based on the above idea, previous studies have adopted a shortranged anisotropic interaction between different species into their models [10][11][12], with which they succeeded in reproducing the closed-loop phase diagram. As these existing studies have been carried out with on-lattice-based structures and/or spatially discretized anisotropic interactions, however, the shape and the statistical properties of the molecular complexes at temperatures below the LCST can be artifacts of the discretizations assumed in their models.…”

Section: Introductionmentioning

confidence: 99%

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Phase behavior of a binary fluid mixture of quadrupolar molecules

et al. 2016

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We propose a model molecule to investigate microscopic properties of a binary mixture with a closed-loop coexistence region. The molecule is comprised of a Lennard-Jones particle and a uniaxial quadrupole. Gibbs ensemble Monte Carlo simulations demonstrate that the high-density binary fluid of the molecules with the quadrupoles of the same magnitude but of the opposite signs can show closed-loop immiscibility. We find that an increase in the magnitude of the quadrupoles causes a shrinkage of the coexistence region. Molecular dynamics simulations also reveal that aggregates with two types of molecules arranged alternatively are formed in the stable one-phase region both above and below the coexistence region. String structures are dominant below the lower critical solution temperature, while branched aggregates are observed above the upper critical solution temperature. We conclude that the anisotropic interaction between the quadrupoles of the opposite signs plays a crucial role in controlling these properties of the phase behavior.

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Section: Results and Discussion For Gemc Simulationssupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Phase behavior of a binary fluid mixture of quadrupolar molecules

et al. 2016

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“…Liquid-liquid immiscibility leading to such phase diagrams is often attributed to hydrogen bonding. 43,44 Complete mixing will occur if the temperature is sufficiently high so as to overcome the enthalpic incompatibility of mixing. However, at sufficiently low temperatures, miscibility results from hydrogen bonding between different components in the system.…”

Section: Introductionmentioning

confidence: 99%

Re-entrant phase behavior for systems with competition between phase separation and self-assembly

Reinhardt

Williamson

Doye

et al. 2011

The Journal of Chemical Physics

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In patchy particle systems where there is a competition between the self-assembly of finite clusters and liquid-vapor phase separation, re-entrant phase behavior can be observed, with the system passing from a monomeric vapor phase to a region of liquid-vapor phase coexistence and then to a vapor phase of clusters as the temperature is decreased at constant density. Here, we present a classical statistical mechanical approach to the determination of the complete phase diagram of such a system. We model the system as a van der Waals fluid, but one where the monomers can assemble into monodisperse clusters that have no attractive interactions with any of the other species. The resulting phase diagrams show a clear region of re-entrance. However, for the most physically reasonable parameter values of the model, this behavior is restricted to a certain range of density, with phase separation still persisting at high densities.

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“…Computer simulations can provide molecular-level insight into phase transition behaviors, as demonstrated in the cases of water and aqueous solutions 29 30 31 32 ; however, to date there are few simulation studies that demonstrate heat-induced spontaneous phase separation of aqueous amphiphilic solutions and try to answer the question as to which factors, hydrogen bonds between unlike molecules or the hydrophobic effect, play a critical role in demixing upon heating 33 34 35 36 .…”

mentioning

confidence: 99%

Liquid–liquid phase separation of N-isopropylpropionamide aqueous solutions above the lower critical solution temperature

Mochizuki

Sumi

Koga

2016

Sci Rep

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We investigate driving forces of the liquid–liquid phase separation of N-isopropylpropionamide (NiPPA) aqueous solutions above the lower critical solution temperature using molecular dynamics simulations. Spontaneous phase separations of the model aqueous solution with a modified OPLS-AA force field are observed above the experimentally determined cloud point. The destabilization toward the phase separation is confirmed by temperature dependence of the long-wavelength limit of the concentration-concentration structure factor, the dominant component of which is found to be an increasing effective attraction between NiPPA molecules. At varying temperatures, the potentials of mean force (PMFs) between a pair of NiPPA molecules at infinite dilution are obtained and decomposed into the nonpolar and Coulombic contributions. The nonpolar contribution, arising essentially from molecular volume, promotes association of NiPPA molecules with increasing temperature while the Coulombic one antagonizes the association. Thus, our analysis leads to a conclusion that the driving force of thermally induced aggregation of NiPPA molecules is the temperature dependence of the nonpolar contribution in PMF between NiPPA molecules, not the temperature dependence of the number or strength of hydrogen bonds between NiPPA and water molecules.

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Simulation Study of the Link between Molecular Association and Reentrant Miscibility for a Mixture of Molecules with Directional Interactions

Cited by 25 publications

References 54 publications

Phase behavior of a binary fluid mixture of quadrupolar molecules

Phase behavior of a binary fluid mixture of quadrupolar molecules

Re-entrant phase behavior for systems with competition between phase separation and self-assembly

Liquid–liquid phase separation of N-isopropylpropionamide aqueous solutions above the lower critical solution temperature

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