Asymptotic properties of bridging transitions in sinusoidally-shaped slits

Abstract

We study bridging transitions that emerge between two sinusoidally-shaped walls of amplitude A, wavenumber k, and mean separation L. The focus is on weakly corrugated walls to examine the properties of bridging transitions in the limit when the walls become flat. The reduction of walls roughness can be achieved in two ways which we show differ qualitatively: a) By decreasing k, (i.e., by increasing the system wavelength), which induces a continuous phenomenon associated with the growth of bridging films concentrated near the system necks, the thickness of with the thickness of these films diverging as k-2/3 in the limit of k0. Simultaneously, the location of the transition approaches that of capillary condensation in an infinite planar slit of an appropriate width as k2/3; b) in contrast, the limit of vanishing walls roughness by reducing A cannot be considered in this context, as there exists a minimal value A min(k,L) of the amplitude below which bridging transition does not occur. On the other hand, for amplitudes A>A min(k,L), the bridging transition always precedes global condensation in the system. These predictions, including the scaling property A min kL2, are verified numerically using density functional theory.

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