Multi‐Scale Superhydrophobic Surface with Excellent Stability and Solar‐Thermal Performance for Highly Efficient Anti‐Icing and Deicing

Abstract

AbstractIce accretion can significantly impact the efficiency and safety of outdoor equipment. Solar‐thermal superhydrophobic surface is an effective strategy for anti‐icing and deicing. However, droplets easily turn to the Wenzel state during the icing and melting cycle processes, significantly increasing the adhesion and making the droplets difficult to remove from the surface. In this work, a triple‐scale solar‐thermal superhydrophobic surface is prepared on stainless steel 304 by etching, in situ oxidation, and spin‐coating TiN nanoparticles for highly efficient deicing and anti‐icing. The multi‐scale structure enabled the droplets to recover the Cassie state completely after melting. The contact angle decreased from 162.5° to 136.7° during the icing process and gradually increased to 162.1° during the melting process. In addition, metal oxides and TiN nanoparticles enabled the superhydrophobic surface to exhibit a high solar absorptivity ( = 0.925). The synergistic effect of the superhydrophobicity and the solar‐thermal performance endowed the designed multi‐scale surface with excellent anti‐icing and deicing performance. This work contributed to the practical development of anti‐icing and deicing applications based on solar‐thermal superhydrophobic surfaces.