Dynamic projection on Feshbach molecules: a probe of pairing and phase fluctuations

TL;DR

This paper presents a simple model linking molecule momentum distribution during rapid Feshbach sweeps in ultracold Fermi gases to initial state properties, revealing phase fluctuation effects and a nonmonotonic condensate fraction behavior.

Contribution

It introduces a model that connects sweep dynamics to initial pairing and phase fluctuations, enabling detection of pseudogap phases in ultracold Fermi systems.

Findings

Phase fluctuations reduce observed condensate fraction near resonance.

Fast sweeps and low temperatures cause nonmonotonic condensate fraction dependence on detuning.

Total molecule number during sweeps probes initial pairing and phase fluctuations.

Abstract

We describe and justify a simple model for the dynamics associated with rapid sweeps across a Feshbach resonance, from the atomic to the molecular side, in an ultra cold Fermi system. The model allows us to relate the observed molecule momentum distribution, including its dependence on the sweep rate, to equilibrium properties of the initial state. For initial state near resonance, we find that phase fluctuations sharply reduce the observed condensate fraction. Moreover, for very fast sweeps and low temperatures, we predict a surprising nonmonotonic dependence of the molecule condensate fraction on detuning, that is a direct signature of quantum phase fluctuations. The dependence of the total molecule number on sweep rate is found to be a sensitive probe of pairing in the initial state, whether condensed or not. Hence it can be utilized to establish the presence of a phase fluctuation induced `psuedogap' phase in these systems.