Relaxation Dynamics of a Liquid in the Vicinity of an Attractive Surface: The Process of Escaping from the Surface

We analyze the displacements of the particles of a liquid perpendicular to an attractive confining surface, using extensive molecular dynamics simulations. Because of the attraction of the surface, the particles are trapped in its vicinity. This leads to a three-step relaxation of the liquid close to the surface. The first step is related to the rattling motions of the particles in the cages formed by their nearest neighbors; the second step is related to small-scale movements close to the surface, and the third step is associated with the process of escaping from the surface. The three-step relaxation is seen through the self-intermediate scattering function or the mean squared displacement of the particles. Upon reducing temperature, the second and third relaxation steps seem to be gradually merged. The solid surface induces also a strong heterogeneity in the mobility of its adjacent particles. This can be seen from the large peak of the non-Gaussian parameter for the particle displacements, which concurs with the appearance of the third step in the relaxation functions. The surface-induced dynamical heterogeneity increases with decreasing temperature.