Molecular understanding of dynamical properties of the vapor/ethanol-aqueous-solution interface

Abstract

The variation of dynamical properties of the vapor/ethanol-aqueous-solution interface with excess adsorption of ethanol is investigated by a molecular dynamics (MD) simulation. Five independent NVT (T = 298.15 K) constant MD runs were performed, where a slab of ethanol-aqueous-solution with ethanol mole fraction of 0.0052, 0.012, 0.024, 0.057 and 0.12, respectively, reached an equilibrium state of adsorption. The positional dependence of molecular self-diffusivity was evaluated by profiles of the self-diffusion coefficient of ethanol and water along the axis normal to the interface. The profile of the ethanol self-diffusion coefficient showed local extrema at the interface, the degree of which is weakened with increase of . Lateral self-diffusivity of an adsorbed ethanol molecule was also evaluated by the two-dimensional (2D) self-diffusion coefficient at the interface, which is a monotonically decreasing function of ethanol excess adsorption. Moreover, the desorption probability of an adsorbed ethanol molecule was estimated, which monotonically increases with ethanol excess adsorption. The molecular origin of the variation of these dynamical properties was explained by correlating them with the profile of the free energy change.