Design and Characterization of Deformable Superstructures Based on Amine-Acrylate Liquid Crystal Elastomers

Deformable superstructures are man-made materials with large deformation properties that surpass those of natural materials. However, traditional deformable superstructures generally use conventional materials as substrates, limiting their applications in multi-mode reconfigurable robots and space-expandable morphing structures. In this work, amine-acrylate-based liquid crystal elastomers (LCEs) are used as deformable superstructures substrate to provide high driving stress and strain. By changing the molar ratio of amine to acrylate, the thermal and mechanical properties of the LCEs are modified. The LCE with a ratio of 0.9 exhibited improved polymerization degree, elongation at break, and toughness. Besides an anisotropic finite deformation model based on hyperelastic theory is developed for the LCEs to capture the configuration variation under temperature activation. Built upon these findings, an LCE-based paper-cutting structure with negative Poisson's ratio and a 2D lattice superstructure model are combined, processed, and molded by laser cutting. The developed superstructure is pre-programmed to the configuration required for service conditions, and the deformation processes are analyzed using both experimental and finite element methods. This study is expected to advance the application of deformable superstructures and LCEs in the fields of defense and military, aerospace, and bionic robotics. Liquid crystal elastomers (LCEs) based on amine-acrylate chemistry are utilized as the substrate for the development of deformable superstructures. High driving stress and strain are achieved by optimizing the molar ratio of amine and acrylate. Built upon finite element simulation, origami-inspired and 2D lattice superstructures are developed, exhibiting reversible and controlled deformations.image

Automated summary

This study focuses on the development of deformable superstructures using liquid crystal elastomers (LCEs) as substrates. By optimizing the molar ratio of amine and acrylate, high driving stress and strain are achieved. A finite deformation model based on hyperelastic theory is developed to capture the configuration variation of the LCEs. The developed superstructures exhibit reversible and controlled deformations, and have potential applications in defense and military, aerospace, and bionic robotics.