The ability to tune the interactions in ultracold gases of fermionic atoms provides a versatile test bed for studying quantum many-body phenomena; unlocking new ways to study condensed matter physics in an environment free of defects. We present measurements of the dynamics of a strongly interacting Fermi gas after a quantum quench of the inter-atomic interactions. In a first study, we measure the time dependent formation dynamics of a pair-condensate after a quench from a weakly attractive Fermi gas to the unitary limit, which involves crossing the normal to superfluid transition. We also find that the short-range correlations are developed far more rapidly than the long-range correlations needed to form a Bose-Einstein condensate. Finally, we present initial measurements showing oscillations in the amplitude of the superfluid order parameter in a trapped Fermi gas induced by quenching the s-wave scattering length in the superfluid phase.
About the presenter
Dr Paul Dyke is currently a research fellow at Swinburne University of Technology. Within FLEET, Dr Dyke is working in Research theme 3, he is experimentally studying Floquet topological superfluidity, non-equilibrium enhancements to superfluids and 2D topological insulators in synthetic dimensions.
