Effect of Population Imbalance on Vortex Mass in Superfluid Fermi Gases

TL;DR

This paper investigates how population imbalance and temperature affect the vortex mass in superfluid Fermi gases, revealing conditions that could enable experimental observation of this fundamental property.

Contribution

It introduces a theoretical framework to analyze the impact of population imbalance on vortex mass, emphasizing the importance of temperature in superfluid Fermi gases.

Findings

Vortex mass varies significantly with temperature and imbalance.

Imbalance can enhance or diminish vortex mass depending on conditions.

Identifies parameter regimes favorable for experimental detection.

Abstract

One of the fundamental parameters associated with quantized vortices in superfluids is the vortex mass, which is the inertia of a vortex. As of yet, this mass has not been observed in a superfluid. However, ultracold Fermi gases provide a promising platform in which recently much experimental progress was made, offering tunability of the interaction as well as control on the single-vortex level. Not only can the scattering length be freely tuned, allowing exploration of the BEC-BCS crossover, but also an imbalance between different pseudospin states can be introduced. We study the effect of introducing this imbalance on the vortex mass, using a method based on an effective field theory for superfluid Fermi gases. We find that it is crucial to consider the imbalance in conjunction with nonzero temperatures; at some temperatures, the vortex mass is significantly enhanced while at others, the vortex mass is diminished. This pronounced temperature dependence highlights the need for careful tuning of experimental conditions and identifies favorable parameter regimes in which the vortex mass is likely to be observed.