In this study, a bioinspired hierarchical structure was formed with superomniphobicity on a 7075 aluminium alloy using laser ablation. The morphology and wetting characteristics of the biomimetic sample surface were characterised using scanning electron microscopy, laser confocal microscopy, and contact angle measurements. The effect of the liquid properties and surface structures on the rolling behaviour was investigated. The results suggest that the fabricated biomimetic sample surface was a hierarchical structure. The prepared sample had superomniphobicity and low adhesion properties, and the contact angles of six different liquid droplets on the sample surface reached or approached 150°. Specifically, the largest contact angle was 152°, and the average rolling angle was 7.7°. This multi‐hydrophobic surface provides a valuable reference for the research study and use of a variety of solid–liquid contacts.
At present, bioinspired functional surfaces have garnered widespread research attention due to the application of directional droplets movement. Herein, inspired by the anisotropic of rice leaves and conical structures of cactus, a bionic wedge‐shaped surface with microstructure of “rice leaf” based on the laser method is reported. In addition, the impact of the microstructure geometrical parameters in the wedge‐shaped surface on the droplet moving anisotropy and manipulation capacity is discussed. Herein, it is found that the movement distance of droplets is effectively improved by regulating the rib‐like microstructure topography and changing the wedge angle. Meanwhile, the movement distance and spreading direction of droplets are controlled by constructing an alternating interface. The results demonstrate that the droplet got optimal displace distance, up to 13 mm by 6.43 s, with the rib‐like microstructure of 0.03 mm and the wedge angle of 10°. When the droplet volume is 40 μL, the droplet is able to separate from the control distance in the alternating interface, after that the droplet moves along the new microstructure direction in the wedge‐shaped surface. Herein, it provides a useful reference for droplet directional movement and water collection.
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