Litcius/Paper detail

Ultra-low ice-substrate adhesion and self-deicing during droplet impact freezing

Pu-Hang Jin, Xiao Yan, Muhammad Jahidul Hoque, Kazi Fazle Rabbi, Soumyadip Sett, Jingcheng Ma, Jiaqi Li, Xiaolong Fang, James Carpenter, Saijie Cai, Wen‐Quan Tao, Nenad Miljkovic

2022Cell Reports Physical Science26 citationsDOIOpen Access PDF

Abstract

A water droplet impacting onto a supercooled surface is typically considered to freeze and adhere to the substrate. This ice accretion poses safety and economic threats to transportation infrastructure, power generation/transmission systems, and telecommunication facilities. Here we report the observation of ultra-low ice-substrate adhesion (0–50 kPa) and remarkable self-deicing during droplet-impact freezing on copper surfaces having medium to high supercooling (30°C–80°C). Mechano-thermo-hydraulic coupling during droplet-impact freezing governs the ice-substrate adhesion by gapping the droplet-substrate contact, enabling self-peeling facilitated by thermal-mechanical stress relaxation. We observe a strong adhesion region in the center of the frozen droplet, which determines the adhesion strength, and develop a regime map to delineate the dependence of adhesion/peeling on droplet inertia, substrate supercooling, and surface wettability. Our work demonstrates key mechanisms governing ice-substrate adhesion during impact icing and presents an approach to passive self-deicing.

Topics & Concepts

SupercoolingIcingAdhesionMaterials scienceWettingSubstrate (aquarium)Ice formationComposite materialIce nucleusGeologyMeteorologyChemistryNucleationAtmospheric sciencesOceanographyOrganic chemistryPhysicsSurface Modification and SuperhydrophobicityIcing and De-icing TechnologiesAdhesion, Friction, and Surface Interactions