Molecular dynamics simulation study on the mass transfer across vapor–liquid interfaces in azeotropic mixtures

Bråten, Vilde; Schaefer, Dominik; Stephan, Simon; Hasse, Hans

doi:10.1063/5.0165421

Cited by 5 publications

(1 citation statement)

References 41 publications

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“…Figure also shows that in some cases, an enrichment of the low-boiling component was observed at the interface. The enrichment (quantifying the relative peak height of the profiles) is an interesting property, as it is suspected to influence the mass transfer across interfaces, , which is also likely relevant for evaporating droplets on walls.…”

Section: Results and Discussionmentioning

confidence: 99%

Molecular Dynamics Study of Adsorption and Wetting of Mixtures of Simple Fluids on Planar Walls

Fertig,

Hasse,

Stephan

2024

J. Phys. Chem. C

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The influence of molecular interactions on the adsorption and wetting of binary mixtures was studied by molecular dynamics simulations of sessile droplets on planar walls. The results provide insights into the competing effects between the fluid− fluid interactions and the solid−fluid interactions on the adsorption and wetting of mixtures. All interactions were modeled by the Lennard-Jones truncated−shifted (LJTS) potential. The influence of the different dispersive interactions in the fluid mixture as well as those between the fluid components and the wall on the gas and liquid adsorption, the three-phase contact, and the contact angle was determined. For the fluid mixtures studied in the present work, the phase behavior and the vapor−liquid interfacial properties are known from recent studies. Together with the present results, this provides a comprehensive picture of the influence of different molecular interactions on the closely related phenomena of wetting and adsorption in mixtures.

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Section: Results and Discussionmentioning

confidence: 99%

Molecular Dynamics Study of Adsorption and Wetting of Mixtures of Simple Fluids on Planar Walls

Fertig,

Hasse,

Stephan

2024

J. Phys. Chem. C

Self Cite

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Vapor‐liquid interfacial properties of binary mixtures from molecular simulation and density gradient theory

Großmann,

Stephan,

Langenbach

et al. 2024

AIChE Journal

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Properties of the vapor‐liquid interface of 16 binary mixtures were studied using molecular dynamics simulations and density gradient theory in combination with the PCP‐SAFT equation of state. All binary combinations of the heavy‐boiling components (cyclohexane, toluene, acetone, and carbon tetrachloride) with the light‐boiling components (methane, carbon dioxide, hydrogen chloride, and nitrogen) were investigated at 0.7 times the critical temperature of the heavy‐boiling component in the whole composition range. Data on the surface tension, the enrichment, the relative adsorption, and the interfacial thickness, as well as for the vapor‐liquid equilibrium and Henry's law constant are reported. The binary interaction parameters were fitted to experimental data in a consistent way for all systems and both methods. Overall, the results from both methods agree well for all investigated properties. The interfacial properties of the different studied systems differ strongly. We show that these differences are directly related to the underlying phase equilibrium behavior.

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Insight into the thermodynamic and mass transport characteristics at the vapor-liquid interface of liquid helium-4 using quantum-corrected EXP-6 potential: A molecular dynamics study

Zhang,

Li,

Chen

et al. 2025

International Communications in Heat and Mass Transfer

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Molecular dynamics simulation study on the mass transfer across vapor–liquid interfaces in azeotropic mixtures

Cited by 5 publications

References 41 publications

Molecular Dynamics Study of Adsorption and Wetting of Mixtures of Simple Fluids on Planar Walls

Molecular Dynamics Study of Adsorption and Wetting of Mixtures of Simple Fluids on Planar Walls

Vapor‐liquid interfacial properties of binary mixtures from molecular simulation and density gradient theory

Insight into the thermodynamic and mass transport characteristics at the vapor-liquid interface of liquid helium-4 using quantum-corrected EXP-6 potential: A molecular dynamics study

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