A droplet that impacts on a superhydrophobic surface
will undergo
a process of unfolding, contracting, and finally rebounding from the
surface. With regards to the pancake bouncing behavior of a droplet,
since the retraction process of the droplet is omitted, the contact
time is greatly shortened compared to the normal type of bouncing.
However, the quantitative prediction to the range of droplet pancake
bouncing and the adjustment of pancake bouncing state have yet to
be probed into. In this paper, we reported the controllable pancake
bouncing of droplets by adjusting the size of the superhydrophobic
surface with microstructures. In addition, we also discovered a dimensional
effect with regards to pancake bouncing, namely, the pancake bouncing
would be more likely to happen on the surfaces with large post spacing
for the droplet with the larger radius. The contact time could be
reduced to 2 ms by adjusting the size of the microstructures and the
radius of the droplets. Based on the relationship between the droplet
bouncing state and the surface microstructure size, we are able to
propose reasonable dimensions for the surfaces in order to control
pancake bouncing.