Effects of magnetic dipole-dipole interactions in atomic Bose-Einstein condensates with tunable s-wave interactions

TL;DR

This paper investigates how magnetic dipole-dipole interactions influence atomic Bose-Einstein condensates with tunable s-wave interactions, providing theoretical predictions and experimental guidance for observing dipolar effects.

Contribution

It introduces a variational method to analyze MDDI effects in BECs with tunable interactions and predicts observable phenomena in specific atomic species.

Findings

Excellent agreement with previous $^{52}$Cr experiments

Predicted observable MDDI effects in $^{7}$Li, $^{39}$K, and $^{133}$Cs

Provided a quantitative parameter for experimental feasibility

Abstract

The s-wave interaction is usually the dominant form of interactions in atomic Bose-Einstein condensates (BECs). Recently, Feshbach resonances have been employed to reduce the strength of the s-wave interaction in many atomic speicies. This opens the possibilities to study magnetic dipole-dipole interactions (MDDI) in BECs, where the novel physics resulting from long-range and anisotropic dipolar interactions can be explored. Using a variational method, we study the effect of MDDI on the statics and dynamics of atomic BECs with tunable s-wave interactions. We benchmark our calculation against previously observed MDDI effects in $^{52}$Cr with excellent agreement, and predict new effects that should be promising to observe experimentally. A parameter of magnetic Feshbach resonances, $\epsilon_{dd,\text{max}}$, is used to quantitatively indicate the feasibility of experimentally observing MDDI effects in different atomic species. We find that strong MDDI effects should be observable in both in-trap and time-of-flight behaviors for the alkali BECs of $^{7}$Li, $^{39}$K, and $^{133}$Cs. Our results provide a helpful guide for experimentalists to realize and study atomic dipolar quantum gases.