Mesoscale structure of chiral nematic shells Article

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Overview

abstract

• There is considerable interest in understanding and controlling topological defects in nematic liquid crystals (LCs). Confinement, in the form of droplets, has been particularly effective in that regard. Here, we employ a Landau-de Gennes formalism to explore the geometrical frustration of nematic order in shell geometries, and focus on chiral materials. By varying the chirality and thickness in uniform shells, we construct a phase diagram that includes tetravalent structures, bipolar structures (BS), bent structures and radial spherical structures (RSS). It is found that, in uniform shells, the BS-to-RSS structural transition, in response to both chirality and shell geometry, is accompanied by an abrupt change of defect positions, implying a potential use for chiral nematic shells as sensors. Moreover, we investigate thickness heterogeneity in shells and demonstrate that non-chiral and chiral nematic shells exhibit distinct equilibrium positions of their inner core that are governed by shell chirality c. © The Royal Society of Chemistry.

authors

• Armas-Pérez J.C.
• De Pablo J.J.
• Guo A.
• Martínez González José Adrián
• Rahimi M.
• Sadati M.
• Zhang R.
• Zhou Y.

publication date

• 2016-01-01

funding provided via

• Basic Energy Sciences, BES  Grant
• Division of Materials Research, DMR: DE-SC0004025  Grant
• U.S. Department of Energy, USDOE  Grant

published in

• Soft Matter  Journal

Research

keywords

• Chirality; Defects; Geometry; Shells (structures); Bipolar structure; Chiral material; Equilibrium positions; Geometrical frustrations; Mesoscale structure; Spherical structures; Structural transitions; Topological defect; Nematic liquid crystals

Identity

Digital Object Identifier (DOI)

• 10.1039/c6sm01284a

Additional Document Info

start page

• 8983

end page

• 8989

volume

• 12

issue

• 44