How Droplets Move on Surfaces with Directional Chemical Heterogeneities

TL;DR

This study demonstrates that droplets exhibit direction-dependent adhesion on asymmetric biphilic surfaces, with the shape and arrangement of chemical patches influencing the adhesion forces and contact line behavior.

Contribution

It provides quantitative analysis of how surface heterogeneity and patch geometry affect droplet adhesion and movement, advancing understanding of wetting on complex surfaces.

Findings

Adhesion varies with direction on asymmetric biphilic surfaces.

Droplet contact line pinning depends on patch shape and orientation.

Asymmetry cancels when patches are more slender.

Abstract

The nature of adhesion of droplets to surfaces is a long pending scientific question. With the evolution of complex surfaces, quantification and prediction of these forces become intricate. Nevertheless, understanding these forces is highly relevant for explaining liquid transport in nature and establishing design guidelines for manmade interfaces. Here, it is shown that the adhesion of droplets is highly sensitive to the directionality of chemical heterogeneities. Asymmetric biphilic surfaces, with hydrophilic triangular patches and superhydrophobic surrounding, impose direction-dependent adhesion. This dependency is quantified by bending beam experiments, in which a droplet is dragged on the surface in two opposite directions. In addition, force calculation derived from droplet roll-off experiments reveal accordant trends. The lower the aspect ratio, the higher the difference of adhesion forces between the two directions. The shape of the fluid contact line on the biphilic surfaces elucidates the origin of the direction-dependent adhesion. Namely, the droplet receding part pins to a higher number of patches when moving toward to apex in comparison to the opposite direction. When the triangular patches are more slender, this asymmetry cancels. These findings improve the understanding of droplet adhesion to biphilic surfaces particularly, and surfaces with wetting heterogeneities in general.