Unveiling the Molecular Origin of Vapor-Liquid Phase Transition of Bulk and Confined Fluids
Issued Date
2022-05-01
Resource Type
eISSN
14203049
Scopus ID
2-s2.0-85129256107
Pubmed ID
35566010
Journal Title
Molecules
Volume
27
Issue
9
Rights Holder(s)
SCOPUS
Bibliographic Citation
Molecules Vol.27 No.9 (2022)
Suggested Citation
Jitmitsumphan S., Sripetdee T., Chaimueangchuen T., Tun H.M., Chinkanjanarot S., Klomkliang N., Srinives S., Jonglertjunya W., Ling T.C., Phadungbut P. Unveiling the Molecular Origin of Vapor-Liquid Phase Transition of Bulk and Confined Fluids. Molecules Vol.27 No.9 (2022). doi:10.3390/molecules27092656 Retrieved from: https://repository.li.mahidol.ac.th/handle/20.500.14594/83751
Title
Unveiling the Molecular Origin of Vapor-Liquid Phase Transition of Bulk and Confined Fluids
Other Contributor(s)
Abstract
At temperatures below the critical temperature, discontinuities in the isotherms are one critical issue in the design and construction of separation units, affecting the level of confidence for a prediction of vapor–liquid equilibriums and phase transitions. In this work, we study the molecular mechanisms of fluids that involve the vapor–liquid phase transition in bulk and confinement, utilizing grand canonical (GCE) and meso-canonical (MCE) ensembles of the Monte Carlo simulation. Different geometries of the mesopores, including slit, cylindrical, and spherical, were studied. During phase transitions, condensation/evaporation hysteretic isotherms can be detected by GCE simulation, whereas employing MCE simulation allows us to investigate van der Waals (vdW) loop with a vapor spinodal point, intermediate states, and a liquid spinodal point in the isotherms. Depending on the system, the size of the simulation box, and the MCE method, we are able to identify three distinct groups of vdW-type isotherms for the first time: (1) a smooth S-shaped loop, (2) a stepwise S-shaped loop, and (3) a stepwise S-shaped loop with just a vertical segment. The first isotherm type is noticed in the bulk and pores having small box sizes, in which vapor and liquid phases are close and not clearly identified. The second and the third types occurred in the bulk, cylindrical, and slit mesopores with sufficiently large spaces, where vapor and liquid phases are distinctly separated. Results from our studies provide an insight analysis into vapor–liquid phase transitions, elucidating the effect of the confinement of fluid behaviors in a visual manner.