It
is a great challenge to fabricate a surface with Cassie–Baxter
wettability that can be continuously adjusted from hydrophilicity
to superhydrophobicity by changing of geometric parameters. In this
paper, we propose and demonstrate a bioinspired surface fabricated
by using a projection micro-stereolithography (PμSL) based 3D
printing technique to address the challenge. Independent of materials,
the bioinspired textured surface has a maximum contact angle (CA)
of 171°, which is even higher than that of the omniphobic springtail
skin we try to imitate. Most significantly, we are able to control
the CA of the bioinspired surface in the range of 55–171°
and the adhesion force from 71 to 99 μN continuously by only
changing the geometric parameters of the bioinspired microstructures.
The underlying mechanisms of the CA control of our bioinspired surface
are also revealed by using a multi-phase lattice Boltzmann model.
Furthermore, we demonstrate potential applications in droplet-based
microreactors, nonloss water transportation, and coalescence of water
droplets by employing our 3D-printed bioinspired structures with their
remarkable precise Cassie–Baxter wettability control and petal
effects. The present results potentially pave a new way for designing
next generation functional surfaces for microdroplet manipulation,
droplet-based biodetection, antifouling surfaces, and cell culture.