Dynamics of transport by helical edge states

TL;DR

This paper investigates the dynamic behavior of helical edge states in topological insulators using a microwave experiment, revealing their robust, slow, unidirectional transport of optical angular momentum with potential applications in quantum technologies.

Contribution

It introduces a microwave setup to study the spatiotemporal dynamics of topological edge states, highlighting their slow, defect-immune transport properties.

Findings

Edge states enable unidirectional, defect-immune transport of optical angular momentum.

Transport velocity is 2-3 orders of magnitude slower than light in free space.

Pseudospin-polarized signals are robust against edge defects.

Abstract

Topologically nontrivial band structure of a material may give rise to special states that are confined to the material's boundary and protected against disorder and scattering. Quantum spin Hall effect (QSHE) is a paradigmatic example of phenomenon in which such states appear in the presence of time-reversal symmetry in two dimensions. Whereas the spatial structure of these helical edge states has been largely studied, their dynamic properties are much less understood. We design a microwave experiment mimicking QSHE and explore the spatiotemporal dynamics of unidirectional transport of optical angular momentum (or pseudospin) by edge states. Pseudospin-polarized signal propagation is shown to be immune to scattering by defects introduced along the edge. Its velocity is 2 to 3 orders of magnitude slower than the speed of light in the free space, which may have important consequences for practical applications of topological edge states in modern optical and quantum-information technologies.