Spin-orbit coupled bosons interacting in a two-dimensional harmonic trap
Abstract
A system of bosons in a two-dimensional harmonic trap in the presence of Rashba-type spin-orbit coupling is investigated. An analytic treatment of the ground state of a single atom in the weak-coupling regime is presented and used as a basis for a perturbation theory in the interacting two-boson system. The numerical diagonalization of both the single-particle and the two-boson Hamiltonian matrices allows us to go beyond those approximations and obtain not only the ground state, but also the low-energy spectra and the different energy contributions separately. We show that the expectation value of the spin-orbit term is related to the expectation value of for the eigenstates of the system, regardless of the trapping potential. The low-energy states of the repulsively interacting two-boson system are characterized. With the presence of a sufficiently strong interaction and spin-orbit coupling strength, there is a direct energy-level crossing in the ground state of the system between states of different , the third component of the total angular momentum, that changes its structure. This is reflected in a discontinuity in the different energy terms and it is signaled in the spatial density of the system.
Cite
@article{arxiv.1907.13355,
title = {Spin-orbit coupled bosons interacting in a two-dimensional harmonic trap},
author = {Pere Mujal and Artur Polls and Bruno Juliá-Díaz},
journal= {arXiv preprint arXiv:1907.13355},
year = {2020}
}