Gravity-driven coatings on curved substrates: a differential geometry approach

TL;DR

This paper uses differential geometry to analyze the drainage and spreading of thin liquid films on various curved substrates, providing analytical solutions and experimental validation for complex 3D geometries.

Contribution

It introduces a differential geometry framework for modeling thin film drainage on arbitrary curved surfaces, extending beyond flat and axisymmetric cases.

Findings

Thickness distribution depends on substrate metric and gravity components.

Large spheroids exhibit increasing thickness away from the pole.

Analytical solutions match numerical and experimental results.

Abstract

Although the drainage and spreading processes of thin liquid films on substrates have received growing attention during the last decades, the study of three-dimensional cases is limited to a few studies on flat and axisymmetric substrates. In this work, we exploit differential geometry to study the drainage and spreading of thin films on generic curved substrates. We initially investigate the drainage and spreading processes on spheroidal and paraboloidal substrates by employing an asymptotic expansion in the vicinity of the pole and a self-similar approach, finding that the thickness distribution is set by the substrate metric and tangential gravity force components. Spheroids with a large ratio between height and equatorial radius are characterized by a growing thickness moving away from the pole, and vice versa. The non-symmetric coating on a toroidal substrate shows that larger thicknesses and a faster spreading are attained on the inner region than on the outer region of the torus. An ellipsoid with three different axes is chosen as a testing ground for three-dimensional drainage and spreading. Modulations in the drainage solution are observed, with a different variation of the thickness along the two axes. By imposing the conservation of mass, an analytical solution for the average spreading front is obtained. The analytical and numerical results are in good agreement. The resulting drainage solutions show also a good agreement with experimental measurements obtained from the coating of a curing polymer on diverse substrates.