Abstract
The rebound of impinging droplets is a defining characteristic of superhydrophobic surfaces; yet, such an intriguing interfacial phenomenon can be effectively suppressed by adding a tiny amount of flexible polymers to induce non-Newtonian viscoelastic properties. In this work, however, we demonstrate the promoting effects of surface heating on the rebound of impinging viscoelastic droplets on superhydrophobic surfaces. The underlying mechanism for the promotion is that the local heat transfer at the liquid–solid interface causes the fast evaporation of the liquid and thus the breakup of the formed viscoelastic filaments, which hinder droplet recoiling. Therefore, the lower threshold velocity for rebound increases while the upper threshold velocity for rebound suppression decreases with increasing surface temperature, resulting in a wider regime for droplet rebound in the impact phase diagram. The surface heating effect on liquid–solid interactions also leads to a nontrivial dependence of the contact time on the impact velocity and a linear decrease of the restitution coefficient with the Weber number for diverse bouncing viscoelastic droplets, which can be rationalized by coupling the interfacial force and energy analyses. We envision that these findings would be useful in technological processes requiring control the retention of viscoelastic liquids on solid surfaces.
Highlights
Anti-wetting is an essential ability of biological systems living on the water-covered Earth [1], and various biosurfaces, including plant leaves [2, 3], insect wings [4], and animal feathers [5, 6], were found to be superhydrophobic
If polymer chains are added in water, the downward motion of the spire can be significantly damped by the extensional viscosity near the droplet center, inhibiting droplet–surface contact [28]. This damping effect was identified on superhydrophobic surfaces and it is more pronounced for impinging droplets with high PEO concentrations as the created air cavity is much shallower than of pure water droplets reported in previous studies [40–43]
This phenomenon is attributed to the evaporation and breakup of the formed viscoelastic filaments on the heated superhydrophobic surface, which hinder droplet retraction
Summary
Anti-wetting is an essential ability of biological systems living on the water-covered Earth [1], and various biosurfaces, including plant leaves [2, 3], insect wings [4], and animal feathers [5, 6], were found to be superhydrophobic. The negligible effect of the non-Newtonian normal stress on droplet impact dynamics was further confirmed by directly measuring the flow velocity within the impinging droplet, which suggests that an effective friction arising at the retracting contact line is responsible for the suppression phenomenon [23]. This mechanism is supported by the rejuvenated rebound of non-Newtonian droplets via nanoparticle enwrapping [22], and the direct visualization of viscoelastic ligaments as a polymer-laden droplet sweeps a superhydrophobic surface in the retraction stage [24]
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