Nucleation of wetting films on cylindrical and spherical substrates: A numerical study by the string method
KAUST DepartmentPhysical Sciences and Engineering (PSE) Division
Department of Mathematics and Joint KAUST-HKUST Micro/Nano-Fluidics Laboratory
Permanent link to this recordhttp://hdl.handle.net/10754/552736
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AbstractUsing the mean-field diffuse-interface model for liquid-vapor system and employing the numerical string method, we study the critical nuclei involved in the prewetting transitions on curved substrates. We first introduce three distinct kinds of critical nuclei, namely, the disklike, bandlike, and layerlike ones, which respectively correspond to three possible growth modes of wettingfilms. We show the disklike growth mode to be the only mode for infinite planar substrates. We then turn to cylindrical and spherical substrates, the two simplest but most important geometries in the real world. We focus on the critical nuclei of finite size, through which the wettingfilms may be formed with finite thermodynamic probabilities. It is shown that the disklike growth mode is always the most probable for wettingfilmnucleation and growth as long as a disklike critical nucleus exists. It is also shown that on a cylindrical substrate, the disklike critical nucleus can no longer exist if the substrate radius is smaller than some critical value, comparable to the radius of the disklike critical nucleus on planar substrate. We find that on a cylindrical substrate whose radius is below the critical value, the nucleation and growth of a wettingfilm can only occur through the bandlike critical nucleus. It is worth emphasizing that the results concerning the bandlike and layerlike growth modes can only be obtained from the diffuse-interface model, beyond the macroscopic description based on the line and surface tensions.
CitationNucleation of wetting films on cylindrical and spherical substrates: A numerical study by the string method 2009, 131 (12):124708 The Journal of Chemical Physics
JournalThe Journal of Chemical Physics