Pinning mediated coalescence-induced lateral droplet motion on nanotextured superhydrophobic surface
Abstract
Droplets coalescing on a superhydrophobic surface exhibit coalescence-induced droplet jumping. However, water vapor condensing on a superhydrophobic surface can result in simultaneous formation of condensate droplets with two distinct wetting states, cassie state (CS) and partially wetting (PW) state. Droplets in PW state exhibit high contact angle but are connected to the substrate though a thin liquid condensate column. Coalescence between CS and PW droplets has been recently identified as a possible mechanism for generating droplets exhibiting in-plane roaming motion during dropwise condensation on nanotextured superhydrophobic surfaces. Here, we systematically investigate this phenomenon through experiments on coalescence between sessile droplets in CS and PW state on a nanostructured superhydrophobic surface endowed with a micro-scale hydrophilic spot. Here, a sessile droplet carefully placed on the hydrophilic spot simulates the PW state. Overall, our investigations demonstrate that when a CS droplet coalesces with a PW droplet pinned to a hydrophilic defect, the interaction generates substantial in-plane momentum. We find that when the coalescing CS and PW droplets are nearly of the same size and about ~3 to ~3.5 times the size of the hydrophilic spot pinning the PW droplet, the vertical momentum generation is nearly completely suppressed, and the resulting maxima in in-plane momentum results in detachment of merged droplet from hydrophilic spot and its subsequent in-plane motion.