Delaying
ice and frost formation is one of the key strategies to
mitigate the hazards induced by ice accretion. The current surfaces
for delaying ice formation rely on restricting heterogeneous ice nucleation,
which fails in practical application because dust and impurities from
the environment can serve as undesired nucleation sites and, thus,
promote ice nucleation. Herein, ionogel surfaces are prepared to not
only inhibit ice nucleation but also control ice growth. At −20
°C, the prepared surface enables an unconventional inward ice
growth from the water droplet–air interface, resulting in a
spherical cap ice rather than a normal pointy cap ice. Both experiments
and molecular simulations confirm that the prepared ionogel surface
can efficiently generate an interfacial liquid layer thanks to the
inward ice growth and the
presence of ionic liquid. Such non-frozen interfacial liquid layer
is desired for lowering ice adhesion and preventing frost formation.
Consequently, the ionogel surface exhibits exceptional anti-frost
abilities under cold humid environment (−20 °C, importing
gas 60% RH at 20 °C).