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Advisor(s)
Abstract(s)
The interaction between two disks immersed in a 2D nernatic is investigated i) analytically using the tenser order parameter formalism for the nematic configuration around isolated disks and ii) numerically using finite-element methods with adaptive meshing to minimize the corresponding Landau-de Gennes free energy. For strong homeotropic anchoring, each disk generates a pair of defects with one-half topological charge responsible for the 2D quadrupolar interaction between the disks at large distances. At short distance, the position of the defects may change, leading to unexpected complex interactions with the quadrupolar repulsive interactions becoming attractive. This short-range attraction in all directions is still anisotropic. As the distance between the disks decreases, their preferred relative orientation with respect to the far-field nernatic director changes from oblique to perpendicular.
Description
Keywords
Saturn-Ring Defects Liquid-Crystal Topological Defects Spherical-Particle Phase-Separation Forces Dispersions Simulation Interface Solvent
Citation
TASINKEVYCH, M.; SILVESTRE, N.M.; PATRICIO, P.; GAMA, M. M. T. da - Colloidal interactions in two-dimensional nematics. European Physical Journal E. ISSN 1292-8941. Vol. 9, nr. 4 (2002), p. 341-347.