Symmetry protected skyrmions in 3D spin-orbit coupled Bose gases

TL;DR

This paper investigates 3D skyrmion-like ground states in spin-orbit coupled Bose gases, revealing symmetry-protected topological textures driven by p-wave spatial modes and phase-dependent density distributions.

Contribution

It introduces a variational approach capturing skyrmion-like states in 3D spin-orbit coupled Bose gases, highlighting the role of p-wave modes and symmetry-protected topological textures.

Findings

Identifies two distinct phases with different density symmetries.

Shows the emergence of 3D skyrmion-like spin textures.

Demonstrates a phase transition driven by interaction strength.

Abstract

We present a variational study of pseudo-spin $1/2$ Bose gases in a harmonic trap with weak 3D spin-orbit coupling of $\bmsigma\cdot\mathbf{p}$ type. This spin-orbit coupling mixes states with different parities, which inspires us to approximate the single particle state with the eigenstates of the total angular momentum, i.e. superposition of harmonic $s$-wave and $p$-wave states. As the time reversal symmetry is protected by two-body interaction, we set the variational order parameter as the combination of two mutually time reversal symmetric eigenstates of the total angular momentum. The variational results essentially reproduce the 3D skyrmion-like ground state recently identified by Kawakami {\it et al.}. We show that these skyrmion-like ground states emerging in this model are primarily caused by $p$ wave spatial mode involving in the variational order parameter that drives two spin components spatially separated. We find the ground state of this system falls into two phases with different density distribution symmetries depending on the relative magnitude of intraspecies and interspecies interaction: Phase I has parity symmetric and axisymmetric density distributions, while Phase II is featured with special joint symmetries of discrete rotational and time reversal symmetry. With the increasing interaction strength the transition occurs between two phases with distinct density distributions, while the topological 3D skyrmion-like spin texture is symmetry protected.