De-wetting of evaporating drops on regular patterns of triangular posts

Directional wicking and spreading of liquids can be achieved by regular micro-patterns of specifically designed topographic features that break the reflection symmetry of the underlying pattern. The present study aims to understand the formation and stability of wetting films during the evaporation of volatile liquid drops on surfaces with a micro-pattern of triangular posts arranged in a rectangular lattice. Depending on the density and aspect ratio of the posts, we observe either spherical-cap shaped drops with a mobile three-phase contact line or the formation of circular or angular drops with a pinned three-phase contact line. Drops of the latter class eventually evolve into a liquid film extending to the initial footprint of the drop and a shrinking cap-shaped drop sitting on the film. The drop evolution is controlled by the density and aspect ratio of the posts, while no influence of the orientation of the triangular posts on the contact line mobility becomes evident. Our experiments corroborate previous results of systematic numerical energy minimization, predicting that conditions for a spontaneous retraction of a wicking liquid film depend weakly on the orientation of the film edge relative to the micro-pattern.

Automated summary

Directional wicking and spreading of liquids can be achieved by specifically designed topographic features that break reflection symmetry. This study investigates the formation and stability of wetting films during the evaporation process on surfaces with a micro-pattern of triangular posts. The evolution of drops is controlled by post density and aspect ratio, with no influence of post orientation on contact line mobility. The experiments confirm previous numerical results, showing that the conditions for spontaneous retraction of a wicking film only weakly depend on the edge orientation relative to the micro-pattern.