Air
Cushion Convection Inhibiting Icing of Self-Cleaning Surfaces
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Abstract
Anti-icing surfaces/interfaces
are of considerable importance in various engineering fields under
natural freezing environment. Although superhydrophobic self-cleaning
surfaces show good anti-icing potentials, promotion of these surfaces
in engineering applications seems to enter a “bottleneck”
stage. One of the key issues is the intrinsic relationship between
superhydrophobicity and icephobicity is unclear, and the dynamic action
mechanism of “air cushion” (a key internal factor for
superhydrophobicity) on icing suppression was largely ignored. Here
we report that icing inhibition (i.e., icing-delay) of self-cleaning
surfaces is mainly ascribed to air cushion and its convection. We
experimentally found air cushion on the porous self-cleaning coating
under vacuum environments and on the water/ice-coating interface at
low temperatures. The icing-delay performances of porous self-cleaning
surfaces compared with bare substrate, up to 10–40 min under
0 to ∼−4 °C environments close to freezing rain,
have been accurately real-time recorded by a novel synergy method
including high-speed photography and strain sensing voltage. Based
on the experimental results, we innovatively propose a physical model
of “air cushion convection inhibiting icing”, which
envisages both the static action of trapped air pocket without air
flow and dynamic action of air cushion convection. Gibbs free energy
of water droplets increased with the entropy of air derived from heat
and mass transfer between warmer air underneath water droplets and
colder surrounding air, resulting in remarkable ice nucleation delay.
Only when air cushion convection disappears can ice nucleation be
triggered on suitable Gibbs free energy conditions. The fundamental
understanding of air cushion on anti-icing is an important step toward
designing optimal anti-icing surfaces for practical engineering application