Dynamic tuning of the director field in liquid crystal shells using block copolymers

TL;DR

This study demonstrates reversible, temperature-driven realignment of nematic liquid crystal shells stabilized by block copolymers, revealing complex topological reconfigurations influenced by curvature and elastic energies, with potential applications in sensing and soft actuators.

Contribution

It introduces a method for dynamic, reversible tuning of liquid crystal shell topology using block copolymer stabilization and temperature control, supported by experiments and modeling.

Findings

Realignment occurs near the nematic-isotropic transition temperature.

The realignment temperature depends on shell curvature and LC properties.

Multiple topological defect configurations are identified and analyzed.

Abstract

When a nematic liquid crystal (LC) is confined on a self-closing spherical shell, topological constraints arise with intriguing consequences that depend critically on how the LC is aligned in the shell. We demonstrate reversible dynamic tuning of the alignment, and thereby the topology, of nematic LC shells stabilized by the nonionic amphiphilic block copolymer Pluronic F127. Deep in the nematic phase, the director is tangential to the interface, but upon approaching the temperature TNI of the nematic-isotropic transition, the director realigns to normal. We link this to a delicate interplay between an interfacial tension that is nearly independent of director orientation, and the configuration-dependent elastic deformation energy of an LC confined in a shell. The process is primarily triggered by the heating-induced reduction of the nematic order parameter, hence realignment temperatures differ by several tens of degrees between LCs with high and low TNI, respectively. The temperature of realignment is always lower on the positive-curved shell outside than at the negative-curved inside, yielding a complex topological reconfiguration on heating. Complementing experimental investigations with mathematical modeling and computer simulations, we identify and investigate three different trajectories, distinguished by their configurations of topological defects in the initial tangential-aligned shell. Our results uncover a new aspect of the complex response of LCs to curved confinement, demonstrating that the order of the LC itself can influence the alignment and thereby the topology of the system. They also reveal the potential of amphiphilic block copolymer stabilizers for enabling continuous tunability of LC shell configuration, opening doors for in-depth studies of topological dynamics as well as novel applications in, e.g., sensing and programmed soft actuators.