"Hall" transport of liquid crystal solitons in Couette flow

TL;DR

This paper demonstrates experimentally and numerically that liquid crystal solitons called torons exhibit a Hall-like transverse deflection under shear flow, revealing new topological transport phenomena with potential microfluidic applications.

Contribution

It provides the first experimental and numerical evidence of Hall-like effects in liquid crystal solitons driven by shear flow, linking topological solitons to transverse transport phenomena.

Findings

Torons are deflected perpendicular to shear flow.

Transverse flow component scales as shear rate cubed.

Torons move with a transverse speed larger than the flow velocity.

Abstract

Topology establishes a unifying framework for a diverse range of scientific areas including particle physics, cosmology, and condensed matter physics. One of the most fascinating manifestations of topology in the context of condensed matter is the topological Hall effect, and its relative: the Skyrmion Hall effect. Skyrmions are stable vortex-like spin configurations in certain chiral magnets, and when subject to external electric currents can drift in the transverse direction to the current. These quasi-particles are characterised by a conserved topological charge which in the Skyrmion Hall effect plays the role of electric charges in the ordinary Hall effect. Recently, it has been shown that liquid crystals endowed with chiral properties serve as an ideal testbed for the fundamental investigation of topological solitons, including their two- and three-dimensional realisations. Here, we show experimentally and numerically that three-dimensional solitons aka "torons" exhibit a Hall-like effect when driven by shear flows: the torons are deflected in the direction perpendicular to the shear plane. The experimental results are rationalised in terms of the dynamic Ericksen-Leslie equations, which predict the emergence of the transverse component of the net mass flow, the magnitude of which scales as the 3rd power of the shear rate. The perturbation analysis highlights an interplay of the viscous and chiral elastic torques as the mechanism for the emergence of net transverse currents. Numerical simulations demonstrate, however, that torons are not merely dragged by the flow but move with their own transverse speed, much larger than the average flow velocity in the transverse direction. Our findings may enable responsive microfluidic applications relying on soft topological solitons.