posted on 2013-01-09, 00:00authored byNenad Miljkovic, Ryan Enright, Youngsuk Nam, Ken Lopez, Nicholas Dou, Jean Sack, Evelyn N. Wang
When droplets coalesce on a superhydrophobic nanostructured
surface,
the resulting droplet can jump from the surface due to the release
of excess surface energy. If designed properly, these superhydrophobic
nanostructured surfaces can not only allow for easy droplet removal
at micrometric length scales during condensation but also promise
to enhance heat transfer performance. However, the rationale for the
design of an ideal nanostructured surface as well as heat transfer
experiments demonstrating the advantage of this jumping behavior are
lacking. Here, we show that silanized copper oxide surfaces created
via a simple fabrication method can achieve highly efficient jumping-droplet
condensation heat transfer. We experimentally demonstrated a 25% higher
overall heat flux and 30% higher condensation heat transfer coefficient
compared to state-of-the-art hydrophobic condensing surfaces at low
supersaturations (<1.12). This work not only shows significant
condensation heat transfer enhancement but also promises a low cost
and scalable approach to increase efficiency for applications such
as atmospheric water harvesting and dehumidification. Furthermore,
the results offer insights and an avenue to achieve high flux superhydrophobic
condensation.