Critical Vortex Shedding in a Strongly Interacting Fermionic Superfluid

Abstract

We study the critical vortex shedding in a strongly interacting fermionic superfluid of 6Li across the BEC-BCS crossover. By moving an optical obstacle in the sample and directly imaging the vortices after time of flight, the critical velocity v c for vortex shedding is measured as a function of the obstacle travel distance L. The observed v c increases with decreasing L, where the rate of increase is the highest in the unitary regime. In the deep BEC regime, an empirical dissipation model well captures the dependence of v c on L, characterized by a constant value of η = - d(1/v c) d(1/L). However, as the system is tuned across the resonance, a step increase of η develops about a characteristic distance L c as L is increased, where L c is comparable to the obstacle size. This bimodal behavior is strengthened as the system is tuned towards the BCS regime. We attribute this evolution of v c to the participation of pair breaking in the vortex shedding dynamics of a fermionic superfluid.