Thermal Capillary Wave Growth and Surface Roughening of Nanoscale Liquid Films

Abstract

The well-known thermal capillary wave theory, which describes the capillary spectrum of the free surface of a liquid film, does not reveal the transient dynamics of surface waves, e.g., the process through which a smooth surface becomes rough. Here, a Langevin model is proposed that can capture these dynamics, goes beyond the long-wave paradigm which can be inaccurate at the nanoscale, and is validated using molecular dynamics simulations for nanoscale films on both planar and cylindrical substrates. We show that a scaling relation exists for surface roughening of a planar film and the scaling exponents belong to a specific universality class. The capillary spectra of planar films are found to advance towards a static spectrum, with the roughness of the surface W increasing as a power law of time W t1/8 before saturation. However, the spectra of an annular film (with outer radius h0) are unbounded for dimensionless wavenumber qh0<1 due to the Rayleigh-Plateau instability.