Jennifer Koch, Sian Barbosa, Felix Lang, Artur Widera:Â
🔓 arXiv:2310.11213 (2023)
We probe the response of ultracold, interacting Fermi gases of Lithium (Li) atoms in the BEC-BCS crossover to strong perturbations in space and time via rapidly switched optical disorder potentials with focus on the BEC side. We measure the time evolution of long-range phase coherence quantified via the ability of the gas to expand hydrodynamically. While in the presence of static disorder, the effects on a Bardeen-Cooper-Schrieffer (BCS) type superfluid are predicted to be much smaller compared to a molecular Bose-Einstein condensate (BEC), we find that the quantum properties of a resonantly interacting, unitary Fermi gas are more strongly suppressed in the presence of quenched disorder than in a molecular BEC. For quenches from a disordered potential, we find that the unitary Fermi gas never recovers quantum hydrodynamics for all parameters studied, while a molecular BEC always recovers quantum hydrodynamics, even when the quench leads to strong particle losses of up to 70 %. Temperature measurements indicate an additional heating channel specific to gases close to resonant interactions, leading to strong local dephasing or pair breaking. Our work illustrates the striking difference between the nonequilibrium phase diagram of the time-dependent disordered BEC-BCS crossover compared to that of the static-disorder case. Moreover, our results suggest an important role of local dephasing of fermionic pairs by time-dependent local perturbations, which could be a key contribution to the destruction of macroscopic quantum properties for time-dependent perturbations.