Black
Silicon/Elastomer Composite Surface with Switchable Wettability and
Adhesion between Lotus and Rose Petal Effects by Mechanical Strain
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Abstract
Although many recent studies demonstrate
surfaces with switchable wettability under various external stimuli,
a deliberate effort to self-propel liquid droplets utilizing a surface
wetting mode switch between slippery lotus and adhesive rose petal
states via a mechanical strain has not been made yet, which would
otherwise further benefit microfluidic applications. In this work,
we present a black silicon/elastomer (bSi/elastomer) composite surface
which shows switchable wettability and adhesion across the two wetting
modes by mechanical stretching. The composite surface is composed
of a scale-like nanostructured silicon platelet array that covers
an elastomer surface. The gap between the neighboring silicon platelets
is reversibly changeable as a function of a mechanical strain, leading
to the transition between the two wetting modes. Moreover, the composite
surface is highly flexible although its wetting properties primarily
originate from superhydrophobic bSi platelets. Different wetting characteristics
of the composite surface in various mechanical strains are studied,
and droplet manipulation such as droplet self-propulsion and pick-and-place
using the composite surface is demonstrated, which highlights its
potentials for microfluidic applications