Photopatterned Designer Disclination Networks in Nematic Liquid Crystals

Linear defect‐disclinations are of fundamental interest in understanding complex structures explored by soft matter physics, elementary particles physics, cosmology, and various branches of mathematics. These defects are also of practical importance in materials applications, such as programmable or...

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Bibliographic Details
Published in:Advanced optical materials 2021-08, Vol.9 (16), p.n/a
Main Authors: Guo, Yubing, Jiang, Miao, Afghah, Sajedeh, Peng, Chenhui, Selinger, Robin L. B., Lavrentovich, Oleg D., Wei, Qi‐Huo
Format: Article
Language:English
Subjects:
Assembly
Confining
Cosmology
Crystal defects
Crystal structure
designing and fabrication
Disclinations
Elementary particles
Liquid crystals
Materials science
Microfluidics
Nanoparticles
Nematic crystals
Networks
Optics
photopatterning
Plates
Radius of curvature
topological defects
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Summary:Linear defect‐disclinations are of fundamental interest in understanding complex structures explored by soft matter physics, elementary particles physics, cosmology, and various branches of mathematics. These defects are also of practical importance in materials applications, such as programmable origami, directed colloidal assembly, and command of active matter. Here an effective engineering approach is demonstrated to pattern molecular orientations at two flat confining surfaces that produce complex yet designable networks of singular disclinations of strength 1/2. Depending on the predesigned director patterns at the bounding plates, the produced disclinations are either surface‐anchored, connecting desired sites at the boundaries, or freely suspended in bulk, forming ordered arrays of polygons and wavy lines. The capability is shown to control the radius of curvature, size, and shape of disclinations by varying uniform alignment orientation on one of these confining plates. The capabilities to precisely design and create highly complex 3D disclination networks promise intriguing applications in stimuli‐responsive reconfigurable materials, directed self‐assembly of molecules, micro‐ and nanoparticles, and transport and sorting in microfluidic applications. A versatile approach is proposed to generate complex yet designable networks of topological defect‐disclinations of strength 1/2 in nematic liquid crystals, either suspended in bulk or anchored on substrates, and is demonstrated by using plasmonic photopatterning of molecular orientations at two confining surfaces.
ISSN:2195-1071
2195-1071
DOI:10.1002/adom.202100181