Dipolar interaction in ultra-cold atomic gases

TL;DR

This paper reviews the properties of ultra-cold dipolar atomic gases, focusing on Chromium atoms, highlighting experimental observations of dipolar effects and theoretical analysis of quantum phases in periodic potentials.

Contribution

It provides a comprehensive overview of dipolar interactions in ultra-cold gases, combining experimental results with theoretical insights into quantum phases and metastable states.

Findings

Observation of dipolar effects in Chromium BEC expansion

Enhanced dipolar interactions via Feshbach resonance

Characterization of quantum phases in dipolar systems with periodic potentials

Abstract

Ultra-cold atomic systems provide a new setting where to investigate the role of long-range interactions. In this paper we will review the basics features of those physical systems, in particular focusing on the case of Chromium atoms. On the experimental side, we report on the observation of dipolar effects in the expansion dynamics of a Chromium Bose-Einstein condensate. By using a Feshbach resonance, the scattering length characterising the contact interaction can be strongly reduced, thus increasing the relative effect of the dipole-dipole interaction. Such experiments make Chromium atoms the strongest candidates at present for the achievement of the strong dipolar regime. On the theoretical side, we investigate the behaviour of ultra-cold dipolar systems in the presence of a periodic potential. We discuss how to realise this situation experimentally and we characterise the system in terms of its quantum phases and metastable states, discussing in detail the differences with respect to the case of zero-range interactions.