Curvature directed anchoring and defect structure of colloidal smectic liquid crystals in confinement

Rod-like objects at high packing fractions can form smectic phases, where the rods break rotational and translational symmetry by forming lamellae. Smectic defects thereby include both discontinuities in the rod orientational order (disclinations), as well as in the positional order (dislocations). In this work, we use both experiments and simulations to probe how local and global geometrical frustrations affect defect formation in hard-rod smectics. We confine a particle-resolved, colloidal smectic within elliptical wells of varying size and shape for a smooth variation of the boundary curvature. We find that the rod orientation near a boundary - the anchoring - depends upon the boundary curvature, with an anchoring transition observed at a critical radius of curvature approximately twice the rod length. The anchoring controls the smectic defect structure. By analyzing local and global order parameters, and the topological charges and loops of networks made of the density maxima (rod centers) and density minima (rod ends), we quantify the amount of disclinations and dislocations formed with varying confinement geometry. More circular confinements, having only planar anchoring, promote disclinations, while more elliptical confinements, with antipodal regions of homeotropic anchoring, promote long-range smectic ordering and dislocation formation. Our findings demonstrate how geometrical constraints can control the anchoring and defect structures of liquid crystals - a principle that is applicable from molecular to colloidal length scales.Comment: 22 pages, 15 figure

Efficiency improvements in a dichroic dye-doped liquid crystal Fresnel lens

A dichroic dye-doped liquid crystal Fresnel lens was fabricated and investigated to observe the combination of phase and amplitude modulation based focusing. An anthraquinone dichroic dye was doped into a liquid crystal host, which when in the Fresnel lens configuration generates a Fresnel zone plate with alternating “transparent” and “opaque” zones. The zones were induced by using photo-alignment of a light-sensitive alignment layer to generate the alternating pattern. The voltage dependency of efficiency for the dye doped and pure liquid crystal Fresnel devices were investigated. Incorporation of dyes into the device yielded a significant 4 % improvement in relative efficiency in the lens, giving a maximum of 37 % achieved in the device, much closer to the theoretical 41 % limit when compared with the non dye doped device. The input polarization dependence of efficiency was also investigated, showing very small fluctuations (±1.5 %), allowing further insight into the effect of fabrication method on these liquid crystal Fresnel devices

Dataset associated with "Isotropic liquid crystal elastomers as exceptional photoelastic strain sensors"

Isotropic elastomeric materials containing liquid crystalline mesogenic unit are shown to have exceptionally large photoelastic constants and compliances that outperform commercially available photoelastic sensor materials. This dataset contains the data from various forms of tensile mechanical testing performed on the new materials developed. In these tests, the strain-induced ordering of the mesogenic units was monitored using birefringence measurements, polarised Raman spectroscopy and the guest-host dye effect