Mediation of lubricated air films using spatially periodic dielectrophoretic effect

A stone thrown in a lake captures air as it collides with water and sinks; likewise a rain drop falling on a flat surface traps air bubbles underneath and creates a spectacular splash. These natural occurrences, from bubble entrapment to liquid ejection, happen as air fails to escape from the closing gap between liquid and solid surfaces. Trapping of air is devastating for casting, coating, painting, and printing industries, or those intolerant of water entry noise. Attempts to eliminate the interfering air rely on either reducing the ambient pressure or modifying the solid surfaces. The former approach is inflexible in its implementation, while the latter one is inherently limited by the wetting speed of liquid or the draining capacity of air passages created on the solid. Here, we present a divide and conquer approach to split the thin air gap into tunnels and subsequently squeeze air out from the tunnels against its viscous resistance using spatially periodic dielectrophoretic force. We confirm the working principles by demonstrating suppression of both bubble entrapment and splash upon impacts of droplets on solid surfaces. The violent splash of a droplet caused by residual air pockets trapped during impact on a solid surface appears inevitable. Vo and Tran show how to vent the drop on short notice for a smooth touchdown, harnessing dielectrophoretic forces to create dynamic drainage channels.

Automated summary

The trapping of air between liquid and solid surfaces can lead to various issues, but by splitting the thin air gap into tunnels and using dielectrophoretic force to squeeze air out, it is possible to prevent bubble entrapment in water and the splash caused by droplets impacting solid surfaces. Venting residual air trapped upon impact on a solid surface using dielectrophoretic forces to create dynamic drainage channels can ensure a smooth touchdown of droplets.