Surface anchoring as a control parameter for stabilizing torons, skyrmions, twisted walls, fingers, and their hybrids in chiral nematics

Tai, Jung‐Shen B.; Smalyukh, Ivan I.

doi:10.1103/physreve.101.042702

Cited by 40 publications

(58 citation statements)

References 77 publications

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“…Moreover, the approach could be extended to investigate twisted structures within LC droplets, in the presence of either chiral and achiral molecules, which is an area of intense interest. 49,50 While additional calculations will provide more robust relationships than that shown in eqn (5), having established a quantitative meso-scale correspondence across scales and models will hopefully lead to improved understanding of the behaviour of LC assemblies, which is needed to further advanced applications.…”

Section: Resultsmentioning

confidence: 99%

Engineered liquid crystal nano droplets: insights from multi-scale simulations

2020

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Section: Resultsmentioning

confidence: 99%

Engineered liquid crystal nano droplets: insights from multi-scale simulations

2020

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“…Topological structures in chiral LC‐GNPB were modeled by numerically minimizing the Frank–Oseen free energy functional [ 1 , 25 , 38 ]

where K 11 = 6.4 pN, K 22 = 3 pN, K 33 = 10 pN are the splay, twist and bend elastic constants of 5CB (average elastic constant K = 6.47 pN), [ 38 ] and p is the equilibrium cholesteric pitch. The saddle‐splay deformation and surface energy are not included by assuming strong boundary conditions on the surfaces, consistent with experiments.…”

Section: Methodsmentioning

confidence: 99%

Nematic Order, Plasmonic Switching and Self‐Patterning of Colloidal Gold Bipyramids

et al. 2021

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Dispersing inorganic colloidal nanoparticles within nematic liquid crystals provides a versatile platform both for forming new soft matter phases and for predefining physical behavior through mesoscale molecular-colloidal self-organization. However, owing to formation of particle-induced singular defects and complex elasticity-mediated interactions, this approach has been implemented mainly just for colloidal nanorods and nanoplatelets, limiting its potential technological utility. Here, orientationally ordered nematic colloidal dispersions are reported of pentagonal gold bipyramids that exhibit narrow but controlled polarization-dependent surface plasmon resonance spectra and facile electric switching. Bipyramids tend to orient with their C 5 rotation symmetry axes along the nematic director, exhibiting spatially homogeneous density within aligned samples. Topological solitons, like heliknotons, allow for spatial reorganization of these nanoparticles according to elastic free energy density within their micrometer-scale structures. With the nanoparticle orientations slaved to the nematic director and being switched by low voltages ≈1 V within a fraction of a second, these plasmonic composite materials are of interest for technological uses like color filters and plasmonic polarizers, as well as may lead to the development of unusual nematic phases, like pentatic liquid crystals.

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“…A local disturbance in a director field that is homogeneous in the far-field can be considered as a soliton. These particle-like topological structures have been studied extensively in LCs since they are an ideal material system to obtain controlled, sometimes reconfigurable, topological patterning of condensed matter [15,26,27,[31][32][33][34][35][36][37][38]. Different from previous work, we use achiral LC in combination with two patterned planar alignment surfaces to stabilize soliton-like structures.…”

Section: Discussionmentioning

confidence: 99%

“…This in contrast to previous works where one patterned substrate was combined with a uniformly aligned substrate [15,26,27]. Solitons, or so-called particle-like topological states, are usually studied in chiral LC samples with strong confinement [31][32][33][34][35][36][37], but photo-alignment techniques allow studying soliton structures in less confined configurations [38] and non-chiral cells [15,26,27]. We investigate new soliton-like NLC structures induced by well-designed ring-shaped alignment patterns at the confining substrates.…”

Section: Introductionmentioning

confidence: 98%

Surface Stabilized Topological Solitons in Nematic Liquid Crystals

2020

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Photo-alignment is a versatile tool to pattern the alignment at the confining substrates in a liquid crystal (LC) cell. Arbitrary alignment patterns can be created by using projection with a spatial light modulator (SLM) for the illumination. We demonstrate that a careful design of the alignment patterns allows the stabilization of topological solitons in nematic liquid crystal (NLC) cells, without the need for chirality or strong confinement. The created LC configurations are stabilized by the anchoring conditions imposed at the substrates. The photo-aligned background at both substrates is uniformly planar aligned, and ring-shaped regions with a 180° azimuthal rotation are patterned with an opposite sense of rotation at the top and bottom substrate. A disclination-free structure containing a closed ring of vertically oriented directors is formed when the patterned rings at the top and bottom substrate overlap. Thanks to the topological stability, a vertical director orientation in the bulk is observed even when the centra of both patterned rings are shifted over relatively large distances. The combination of numerical simulations with experimental measurements allows identification of the 3D director configuration in the bulk. A finite element (FE) Q-tensor simulation model is applied to find the equilibrium director configuration and optical simulations are used to confirm the correspondence with experimental microscopy measurements. The created LC configurations offer opportunities in the field of optical devices, light guiding and switching, particle trapping and studies of topological LC structures.

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Surface anchoring as a control parameter for stabilizing torons, skyrmions, twisted walls, fingers, and their hybrids in chiral nematics

Cited by 40 publications

References 77 publications

Engineered liquid crystal nano droplets: insights from multi-scale simulations

Engineered liquid crystal nano droplets: insights from multi-scale simulations

Nematic Order, Plasmonic Switching and Self‐Patterning of Colloidal Gold Bipyramids

Surface Stabilized Topological Solitons in Nematic Liquid Crystals

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