Atoms in a spin dependent optical potential: ground state topology and magnetization

TL;DR

This paper explores how a Bose-Einstein condensate in a spin-dependent optical lattice exhibits topological changes in its ground state due to the interplay of magnetic fields and spin-rotation coupling, revealing complex quantum behaviors.

Contribution

It demonstrates the topological transition of the ground state in a spin-dependent optical lattice influenced by external magnetic fields and spin-rotation effects in a Bose-Einstein condensate.

Findings

Ground state topology changes with magnetic field ratio B_ext/B_fic

Zeeman and Einstein-de Haas effects drive the topological transition

External magnetic field polarizes atoms and alters kinetic energy

Abstract

We investigate a Bose-Einstein condensate of $F= 1$ $^{87}$Rb atoms in a 2D spin-dependent optical lattice generated by intersecting laser beams with a superposition of polarizations. For $^{87}$Rb the effective interaction of an atom with the electromagnetic field contains a scalar and a vector (called as fictitious magnetic field, $B_{fic}$) potentials. The Rb atoms behave as a quantum rotor (QR) with angular momentum given by the sum of the atomic rotational motion angular momentum and the hyperfine spin. The ground state of the QR is affected upon applying an external magnetic field, $B_{ext}$, perpendicular to the plane of QR motion and a sudden change of its topology occurs as the ratio $B_{ext}/B_{fic}$ exceeds critical value. It is shown that the change of topology of the QR ground state is a result of combined action of Zeeman and Einstein-de Haas effects. The first transfers atoms to the largest hyperfine component to polarize the sample along the field as the external magnetic field is increased. The second sweeps spin to rotational angular momentum, modifying the kinetic energy of the atoms.