Coreless vorticity in multicomponent Bose and Fermi superfluids

TL;DR

This paper investigates the conditions under which vortices in multicomponent Bose-Einstein condensates and Fermi gases can have filled cores, revealing phase transitions and phase diagrams for coreless vorticity.

Contribution

It identifies critical parameters for vortex core states and constructs phase diagrams for coreless vorticity in multicomponent superfluids, extending analysis to trapped systems.

Findings

Critical values for phase transition between vortex types

Phase diagram of coreless vorticity in Fermi gases

Extension to trapped systems beyond Thomas-Fermi approximation

Abstract

We consider quantized vortices in two-component Bose-Einstein condensates and three-component Fermi gases with attractive interactions. In these systems, the vortex core can be either empty (normal in the fermion case) or filled with another superfluid. We determine critical values of the parameters -- chemical potentials, scattering lengths and, for Fermi gases, temperature -- at which a phase transition between the two types of vortices occurs. Population imbalance can lead to superfluid core (coreless) vorticity in multicomponent superfluids which otherwise support only usual vortices. For multicomponent Fermi gases, we construct the phase diagram including regions of coreless vorticity. We extend our results to trapped bosons and fermions using an appropriate local approximation, which goes beyond the usual Thomas-Fermi approximation for trapped bosons.