Abstract
We studied the freezing of super-cooled water inside a millimeter-sized copper well by confocal microscopy. During freezing, we surprisingly observed a novel melting scenario, which we call a ‘sudden-melting event’: the ice directly above the bottom substrate suddenly melts in the late stage of the freezing process, while the system is continuously being cooled. After this event, an empty gap around 10 μm to 20 μm between the substrate and the bulk ice is formed. Because this gap occupies the majority of the area of the bottom substrate, the adhesion between the bulk ice and the substrate is greatly reduced: the adhesion force decreases by more than 50% compared with the flat-substrate situation. We further discovered that air dissolved in water plays a crucial role in this melting event: the air excluded by water freezing produces inter-connecting channels in the bulk ice, which transport the warm water produced by latent heat to the substrate which causes the sudden melting event. Because this event makes the contact between ice and substrate very poor, and greatly reduces ice adhesion, our observation may lead to a promising anti-icing method on solid substrates. Compared to the prevalent super-hydrophobic surface technique, our approach only requires millimeter-sized wells instead of complex microscopic textures. Therefore, it is much easier and cheaper to produce, as well as much more robust for large-scale practical applications.
Highlights
The formation and subsequent accumulation of ice on surfaces affects the operation of numerous components of modern infrastructure, including ships, air-cra, offshore oil platforms, dams, wind turbines, power transmission lines, and telecommunications equipment, and introduces lots of damage and loss to our everyday life.[1,2,3] development of robust and easy anti-icing methods is always extremely important, which has attracted lots of attention from various researchers due to great signi cance in our daily life and in industry
Instead of fabricating super-hydrophobic textures, here we report a novel method to directly decrease the contact area between ice and the substrate, from the aspect of surface pro le design and thermodynamics, and achieve a low-cost and highly-robust anti-icing function
We focused on the second stage, because the sudden melting event occurred in this stage
Summary
The formation and subsequent accumulation of ice on surfaces affects the operation of numerous components of modern infrastructure, including ships, air-cra , offshore oil platforms, dams, wind turbines, power transmission lines, and telecommunications equipment, and introduces lots of damage and loss to our everyday life.[1,2,3] development of robust and easy anti-icing methods is always extremely important, which has attracted lots of attention from various researchers due to great signi cance in our daily life and in industry. In the past several decades, with the help of advances in the understanding of liquid–solid interactions,[6,7,8] to acquire ice-phobicity attention has been drawn to super-hydrophobic surfaces with fabrication of nanometer-sized or micrometer-sized textures,[9,10,11,12,13,14,15] spraying hydrophobic organics (like proteins),[16,17,18] adding various hydrophobic coatings,[19,20,21,22] or even ferro uids (combined with a magnetic eld).[23] These strategies show their efficiency in antiicing under experimental conditions, but progress has been
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