Liquid‐Superrepellent Bioinspired Fibrillar Adhesives

Abstract

Abstract Bioinspired elastomeric fibrillar surfaces have significant potential as reversible dry adhesives, but their adhesion performance is sensitive to the presence of liquids at the contact interface. Like their models in nature, many artificial mimics can effectively repel water, but fail when low‐surface‐tension liquids are introduced at the contact interface. A bioinspired fibrillar adhesive surface that is liquid‐superrepellent even toward ultralow‐surface‐tension liquids while retaining its adhesive properties is proposed herein. This surface combines the effective adhesion principle of mushroom‐shaped fibrillar arrays with liquid repellency based on double re‐entrant fibril tip geometry. The adhesion performance of the proposed microfibril structures is retained even when low‐surface‐tension liquids are added to the contact interface. The extreme liquid repellency enables real‐world applications of fibrillar adhesives for surfaces covered with water, oil, and other liquids. Moreover, fully elastomeric liquid‐superrepellent surfaces are mechanically not brittle, highly robust against physical contact, and highly deformable and stretchable, which can increase the real‐world uses of such antiwetting surfaces.