Interference of atomic levels and superfluid -- Mott insulator phase transition in a two-component Bose-Einstein condensate

TL;DR

This paper theoretically explores how internal atomic level interference affects the superfluid to Mott insulator phase transition in a two-component Bose-Einstein condensate within an optical lattice, highlighting the role of laser parameters.

Contribution

It introduces a detailed phase diagram analysis for a two-component BEC in an optical lattice, revealing how laser detuning and polarization influence the phase transition and enable state manipulation.

Findings

Sign of detuning critically affects the Mott transition.

Blue detuning strongly suppresses the Mott transition.

Laser parameters can control phase transition and create distinct superfluid states.

Abstract

The superfluid -- Mott insulator phase transition in a Bose-Einstein condensate of neutral atoms with doubly degenerate internal ground states in an optical lattice is theoretically investigated. The optical lattice is created by two counterpropagating linearly polarized laser beams with the angle $\theta$ between the polarization vectors (lin-angle-lin configuration). The phase diagram of the system and the critical values of the parameters are worked out. It is shown that the sign of the detuning plays an important role and that there is a strong suppression of the Mott transition in the case of blue detuning. Varying the laser intensity and/or the angle $\theta$ one can manipulate the Mott-insulator to superfluid quantum phase transition as well as prepare the condensate in physically distinguishable "ferromagnetic" and "antiferromagnetic" superfluid states.