English

Dislocation Dynamics in an Anisotropic Stripe Pattern

Soft Condensed Matter 2009-11-10 v1 Statistical Mechanics

Abstract

The dynamics of dislocations confined to grain boundaries in a striped system are studied using electroconvection in the nematic liquid crystal N4. In electroconvection, a striped pattern of convection rolls forms for sufficiently high driving voltages. We consider the case of a rapid change in the voltage that takes the system from a uniform state to a state consisting of striped domains with two different wavevectors. The domains are separated by domain walls along one axis and a grain boundary of dislocations in the perpendicular direction. The pattern evolves through dislocation motion parallel to the domain walls. We report on features of the dislocation dynamics. The kinetics of the domain motion are quantified using three measures: dislocation density, average domain wall length, and the total domain wall length per area. All three quantities exhibit behavior consistent with power law evolution in time, with the defect density decaying as t1/3t^{-1/3}, the average domain wall length growing as t1/3t^{1/3}, and the total domain wall length decaying as t1/5t^{-1/5}. The two different exponents are indicative of the anisotropic growth of domains in the system.

Keywords

Cite

@article{arxiv.cond-mat/0404117,
  title  = {Dislocation Dynamics in an Anisotropic Stripe Pattern},
  author = {Carina Kamaga and Fatima Ibrahim and Michael Dennin},
  journal= {arXiv preprint arXiv:cond-mat/0404117},
  year   = {2009}
}

Comments

8 figures: 7 jpeg and 1 pdf