Issue 3, 2023

Structures, thermodynamics and dynamics of topological defects in Gay–Berne nematic liquid crystals

Abstract

Topological defects are a ubiquitous phenomenon across different physical systems. A better understanding of defects can be helpful in elucidating the physical behaviors of many real materials systems. In nematic liquid crystals, defects exhibit unique optical signatures and can segregate impurities, showing their promise as molecular carriers and nano-reactors. Continuum theory and simulations have been successfully applied to link static and dynamical behaviors of topological defects to the material constants of the underlying nematic. However, further evidence and molecular details are still lacking. Here we perform molecular dynamics simulations of Gay–Berne particles, a model nematic, to examine the molecular structures and dynamics of +1/2 defects in a thin-film nematic. Specifically, we measure the bend-to-splay ratio K3/K1 using two independent, indirect measurements, showing good agreement. Next, we study the annihilation event of a pair of ±1/2 defects, of which the trajectories are consistent with experiments and hydrodynamic simulations. We further examine the thermodynamics of defect annihilation in an NVE ensemble, leading us to correctly estimate the elastic modulus by using the energy conservation law. Finally, we explore effects of defect annihilation in regions of nonuniform temperature within these coarse-grained molecular models which cannot be analysed by existing continuum level simulations. We find that +1/2 defects tend to move toward hotter areas and their change of speed in a temperature gradient can be quantitatively understood through a term derived from the temperature dependence of the elastic modulus. As such, our work has provided molecular insights into structures and dynamics of topological defects, presented unique and accessible methods to measure elastic constants by inspecting defects, and proposed an alternative control parameter of defects using temperature gradient.

Graphical abstract: Structures, thermodynamics and dynamics of topological defects in Gay–Berne nematic liquid crystals

Supplementary files

Article information

Article type
Paper
Submitted
31 Aug 2022
Accepted
30 Nov 2022
First published
30 Nov 2022

Soft Matter, 2023,19, 483-496

Author version available

Structures, thermodynamics and dynamics of topological defects in Gay–Berne nematic liquid crystals

Y. Huang, W. Wang, J. K. Whitmer and R. Zhang, Soft Matter, 2023, 19, 483 DOI: 10.1039/D2SM01178F

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