posted on 2017-07-18, 00:00authored byMegan
D. Mulroe, Bernadeta R. Srijanto, S. Farzad Ahmadi, C. Patrick Collier, Jonathan B. Boreyko
It
was recently discovered that condensation growing on a nanostructured
superhydrophobic surface can spontaneously jump off the surface, triggered
by naturally occurring coalescence events. Many reports have observed
that droplets must grow to a size of order 10 μm before jumping
is enabled upon coalescence; however, it remains unknown how the critical
jumping size relates to the topography of the underlying nanostructure.
Here, we characterize the dynamic behavior of condensation growing
on six different superhydrophobic nanostructures, where the topography
of the nanopillars was systematically varied. The critical jumping
diameter was observed to be highly dependent upon the height, diameter,
and pitch of the nanopillars: tall and slender nanopillars promoted
2 μm jumping droplets, whereas short and stout nanopillars increased
the critical size to over 20 μm. The topology of each surface
is successfully correlated to the critical jumping diameter by constructing
an energetic model that predicts how large a nucleating embryo needs
to grow before it can inflate into the air with an apparent contact
angle large enough for jumping. By extending our model to consider
any possible surface, it is revealed that properly designed nanostructures
should enable nanometric jumping droplets, which would further enhance
jumping-droplet condensers for heat transfer, antifogging, and antifrosting
applications.