AI Article Synopsis
- The paper investigates osmotic transport using molecular dynamics simulations, focusing on osmosis through a semi-permeable membrane and analyzing the reflection coefficient in different concentration scenarios.
- It explores diffusio-osmotic flow in a solute-solvent fluid next to a solid surface, driven by a chemical potential gradient, and introduces a new non-equilibrium MD methodology to accurately simulate this process.
- The proposed method is validated using linear-response theory and is applied to more realistic systems like water-ethanol mixtures interacting with silica or graphene surfaces.
Article Abstract
In this paper, we explore osmotic transport by means of molecular dynamics (MD) simulations. We first consider osmosis through a membrane and investigate the reflection coefficient of an imperfectly semi-permeable membrane, in the dilute and high concentration regimes. We then explore the diffusio-osmotic flow of a solute-solvent fluid adjacent to a solid surface, driven by a chemical potential gradient parallel to the surface. We propose a novel non-equilibrium MD (NEMD) methodology to simulate diffusio-osmosis, by imposing an external force on every particle, which properly mimics the chemical potential gradient on the solute in spite of the periodic boundary conditions. This NEMD method is validated theoretically on the basis of linear-response theory by matching the mobility with their Green-Kubo expressions. Finally, we apply the framework to more realistic systems, namely, a water-ethanol mixture in contact with a silica or a graphene surface.
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| http://dx.doi.org/10.1063/1.4981794 | DOI Listing |
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