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Main Authors: Fonseca, Tássylla O., Mendonça, Bruno H. S., de Moraes, Elizane E., de Oliveira, Alan B., Barbosa, Marcia C.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.13089
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author Fonseca, Tássylla O.
Mendonça, Bruno H. S.
de Moraes, Elizane E.
de Oliveira, Alan B.
Barbosa, Marcia C.
author_facet Fonseca, Tássylla O.
Mendonça, Bruno H. S.
de Moraes, Elizane E.
de Oliveira, Alan B.
Barbosa, Marcia C.
contents Through Monte Carlo simulations and the Associating Lattice Gas Model, the phases of a two-dimensional fluid under hydrophilic confinement are evaluated. The model, in its unconfined version, reproduces the anomalous behavior of water regarding its density, diffusion, and solubility, among other dynamic and thermodynamic properties. Extreme confinements suppress phase transitions since fluctuations suppress ordering. The fluid under hydrophilic confinement forms a single wetting layer that gradually wets the wall. From the wetting layer, the low-density liquid structure is formed. The confined fluid presents a first-order liquid-liquid transition, but always at lower temperatures than that observed in the bulk.
format Preprint
id arxiv_https___arxiv_org_abs_2409_13089
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Wetting in Associating Lattice Gas Model Confined by Hydrophilic Walls
Fonseca, Tássylla O.
Mendonça, Bruno H. S.
de Moraes, Elizane E.
de Oliveira, Alan B.
Barbosa, Marcia C.
Applied Physics
Materials Science
Through Monte Carlo simulations and the Associating Lattice Gas Model, the phases of a two-dimensional fluid under hydrophilic confinement are evaluated. The model, in its unconfined version, reproduces the anomalous behavior of water regarding its density, diffusion, and solubility, among other dynamic and thermodynamic properties. Extreme confinements suppress phase transitions since fluctuations suppress ordering. The fluid under hydrophilic confinement forms a single wetting layer that gradually wets the wall. From the wetting layer, the low-density liquid structure is formed. The confined fluid presents a first-order liquid-liquid transition, but always at lower temperatures than that observed in the bulk.
title Wetting in Associating Lattice Gas Model Confined by Hydrophilic Walls
topic Applied Physics
Materials Science
url https://arxiv.org/abs/2409.13089