Ultracold dipolar gas in an optical lattice: the fate of metastable states

TL;DR

This paper explores the emergence, stability, and manipulation of metastable states in ultracold dipolar bosons within optical lattices, highlighting their potential as quantum memories.

Contribution

It introduces a generalized instanton approach to analyze metastable state stability and demonstrates control methods via superlattice modulations.

Findings

Metastable states arise due to dipole-dipole interactions.

Transitions between metastable states involve superfluid intermediates.

Metastable states can be created and manipulated with superlattice techniques.

Abstract

We study the physics of ultracold dipolar bosons in optical lattices. We show that dipole-dipole interactions lead to the appearance of many insulating metastable states. We study the stability and lifetime of these states using a generalization of the instanton theory. We investigate also possibilities to prepare, control and manipulate these states using time dependent superlattice modifications and modulations. We show that the transfer from one metastable configuration to another necessarily occurs via superfluid states, but can be controlled fully on the quantum level. We show how the metastable states can be created in the presence of the harmonic trap. Our findings open the way toward applications of the metastable states as quantum memories.