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Synergistic Adhesion and Shape Deformation in Nanowire‐Structured Liquid Crystal Elastomers

Robert L. Dupont, Yang Xu, Angana Borbora, Xinyu Wang, Xinyu Wang, Fatemeh Azadi, Kaden Havener, Broderick Lewis, Weichen Deng, Benjamin W. Tan, Shucong Li, Rui Zhang, Yuxing Yao, Uttam Manna, Xiaoguang Wang, Xiaoguang Wang

2025Advanced Materials14 citationsDOIOpen Access PDF

Abstract

Nature provides many examples of the benefits of nanoscopic surface structures in areas of adhesion and antifouling. Herein, the design, fabrication, and characterization of liquid crystal elastomer (LCE) films are presented with nanowire surface structures that exhibit tunable stimuli-responsive deformations and enhanced adhesion properties. The LCE films are shown to curl toward the side with the nanowires when stimulated by heat or organic solvent vapors. In contrast, when a droplet of the same solvent is placed on the film, it curls away from the nanowire side due to nanowire-induced capillary forces that cause unequal swelling. This characteristic curling deformation is shown to be reversible and can be optimized to match curved substrates, maximizing adhesive shear forces. By using chemical modification, the LCE nanowire films can be given underwater superoleophobicity, enabling oil repellency under a range of harsh conditions. This is combined with the nanowire-induced frictional asymmetry and the reversible shape deformation to create an underwater droplet mixing robot, capable of performing chemical reactions in aqueous environments. These findings demonstrate the potential of nanowire-augmented LCE films for advanced applications in soft robotics, adaptive adhesion, and easy chemical modification, with implications for designing responsive materials that integrate mechanical flexibility with surface functionality.

Topics & Concepts

Materials scienceNanowireNanotechnologyElastomerAdhesionSoft roboticsNanoscopic scaleBiofoulingFabricationComposite materialAdhesiveMicroscale chemistryDeformation (meteorology)Surface modificationChemical engineeringActuatorLayer (electronics)MedicineGeneticsBiologyMathematics educationPathologyMembraneElectrical engineeringEngineeringAlternative medicineMathematicsAdhesion, Friction, and Surface InteractionsAdvanced Materials and MechanicsSurface Modification and Superhydrophobicity