Emergent topological properties in interacting one-dimensional systems with spin-orbit coupling

TL;DR

This paper investigates how electron interactions in a spin-orbit coupled quantum wire can induce a topological spin-density-wave phase with edge modes, revealing emergent topological properties in a one-dimensional system.

Contribution

It demonstrates that electron-electron interactions can create a topological insulator-like phase in a 1D wire with spin-orbit coupling, a novel finding in low-dimensional topological matter.

Findings

Interaction-induced gap in the spin sector when U < δv

Emergence of a topological spin-density-wave phase with edge modes

Robust conductance similar to 2D spin-Hall edge states

Abstract

We present analysis of a single channel interacting quantum wire problem in the presence of spin-orbit interaction. The spin-orbit coupling breaks the spin-rotational symmetry from SU(2) to U(1) and breaks inversion symmetry. The low-energy theory is then a two band model with a difference of Fermi velocities $\delta v$. Using bosonization and a two-loop renormalization group procedure we show that electron-electron interactions can open a gap in the spin sector of the theory when the interaction strength $U$ is smaller than $\delta v$ in appropriate units. For repulsive interactions, the resulting strong coupling phase is of the spin-density-wave type. We show that this phase has peculiar emergent topological properties. The gapped spin sector behaves as a topological insulator, with zero-energy edge modes with fractional spin. On the other hand, the charge sector remains critical, meaning the entire system is metallic. However, this bulk electron liquid as a whole exhibits properties commonly associated with the one-dimensional edge states of two-dimensional spin-Hall insulators, in particular, the conduction of $2e^2/h$ is robust against nonmagnetic impurities.