Abstract
Liquid crystal elastomers exhibit large reversible strain and programmable shape transformations, enabling various applications in soft robotics, dynamic optics, and programmable origami and kirigami. The morphing modes of these materials depend on both their geometries and director fields. In two dimensions, a pixel-by-pixel design has been accomplished to attain more flexibility over the spatial resolution of the liquid crystal response. Here we generalize this idea in two steps. First, we create independent, cubic light-responsive voxels, each with a predefined director field orientation. Second, these voxels are in turn assembled to form lines, grids, or skeletal structures that would be rather difficult to obtain from an initially connected material sample. In this way, the orientation of the director fields can be made to vary at voxel resolution to allow for programmable optically- or thermally-triggered anisotropic or heterogeneous material responses and morphology changes in three dimensions that would be impossible or hard to implement otherwise.
Highlights
Liquid crystal elastomers exhibit large reversible strain and programmable shape transformations, enabling various applications in soft robotics, dynamic optics, and programmable origami and kirigami
Recent advances in 3D printing technologies have enabled the creation of 3D Liquid crystal elastomers (LCEs) geometries via ink[28,29,30,31,32] and optical 3D printing[10,13,33,34], which allows for 3D-to-3D shape-morphing
Creating the individual LCE voxels with programmable director fields nðx; y; zÞ is the key step in such a process
Summary
Liquid crystal elastomers exhibit large reversible strain and programmable shape transformations, enabling various applications in soft robotics, dynamic optics, and programmable origami and kirigami. Their corresponding azimuthal angle φ and polar angle θ are presented in Supplementary Fig. 1, which a Rotate around z-axis by Rotate around y-axis by c (ii) Voxels with different director fields (iii)Assembled layers (i)Laser writing of voxels with designed director fields in a liquid crystal cell
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