posted on 2018-11-19, 00:00authored byGustav Graeber, Oskar B. Martin Kieliger, Thomas M. Schutzius, Dimos Poulikakos
Macrotextured
superhydrophobic surfaces can reduce droplet–substrate contact
times of impacting water droplets; however, surface designs with similar
performance for significantly more viscous liquids are missing, despite
their importance in nature and technology such as for chemical shielding,
food-staining repellency, and supercooled (viscous) water droplet
removal in anti-icing applications. Here, we introduce a deterministic,
controllable, and upscalable method to fabricate superhydrophobic
surfaces with a 3D-printed architecture, combining arrays of alternating
surface protrusions and indentations. We show a more than threefold
contact time reduction of impacting viscous droplets up to a fluid
viscosity of 3.7 mPa·s, which equals 3.7 times the viscosity
of water at room temperature, covering the viscosity of many chemicals
and supercooled water. On the basis of the combined consideration
of the fluid flow within and the simultaneous droplet dynamics above
the texture, we recommend future pathways to rationally architecture
such surfaces, all realizable with the methodology presented here.