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Thermal capillary wave growth and surface roughening of nanoscale liquid films

Y. Zhang, J.E. Sprittles, D.A. Lockerby

2021Journal of Fluid Mechanics26 citationsDOIOpen Access PDF

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 this 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 $W\sim t^{1/8}$ before saturation. However, the spectra of an annular film (with outer radius $h_0$ ) are unbounded for dimensionless wavenumber $qh_0<1$ due to the Rayleigh–Plateau instability.

Topics & Concepts

Materials scienceCapillary waveCapillary actionDimensionless quantityScalingPlanarNanoscopic scaleWavenumberSurface roughnessThermalSurface finishThermal fluctuationsMechanicsSpectral lineFree surfaceSurface (topology)Molecular dynamicsCondensed matter physicsCapillary surfaceOpticsRADIUSSurface wavePower lawCapillary lengthCapillary numberAmorphous solidSurface tensionThermal conductivityUniversality (dynamical systems)NanofluidicsSpectral densityLangevin dynamicsThin filmDrop (telecommunication)Composite materialFluid Dynamics and Thin FilmsNanomaterials and Printing TechnologiesThermal properties of materials