Solution landscapes in nematic microfluidics
Abstract
We study the static equilibria of a simplified Leslie--Ericksen model for a unidirectional uniaxial nematic flow in a prototype microfluidic channel, as a function of the pressure gradient and inverse anchoring strength, . We numerically find multiple static equilibria for admissible pairs and classify them according to their winding numbers and stability. The case is analytically tractable and we numerically study how the solution landscape is transformed as increases. We study the one-dimensional dynamical model, the sensitivity of the dynamic solutions to initial conditions and the rate of change of and . We provide a physically interesting example of how the time delay between the applications of and can determine the selection of the final steady state.
Cite
@article{arxiv.1607.05054,
title = {Solution landscapes in nematic microfluidics},
author = {Maria Crespo and Ian Griffiths and Apala Majumdar and Angel Ramos},
journal= {arXiv preprint arXiv:1607.05054},
year = {2017}
}