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How Water Advances on Superhydrophobic Surfaces

Overview
Journal Phys Rev Lett
Publisher American Physical Society
Specialty Biophysics
Date 2016 Mar 19
PMID 26991185
Citations 35
Authors
Frank Schellenberger
Noemi Encinas
Doris Vollmer
Hans-Jurgen Butt
Affiliations
Soon will be listed here.
Abstract

Superliquid repellency can be achieved by nano- and microstructuring surfaces in such a way that protrusions entrap air underneath the liquid. It is still not known how the three-phase contact line advances on such structured surfaces. In contrast to a smooth surface, where the contact line can advance continuously, on a superliquid-repellent surface, the contact line has to overcome an air gap between protrusions. Here, we apply laser scanning confocal microscopy to get the first microscopic videos of water drops advancing on a superhydrophobic array of micropillars. In contrast to common belief, the liquid surface gradually bends down until it touches the top face of the next micropillars. The apparent advancing contact angle is 180°. On the receding side, pinning to the top faces of the micropillars determines the apparent receding contact angle. Based on these observations, we propose that the apparent receding contact angle should be used for characterizing superliquid-repellent surfaces rather than the apparent advancing contact angle and hysteresis.

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