Transition from a polaronic condensate to a degenerate Fermi gas of heteronuclear molecules

The interplay of quantum statistics and interactions in atomic Bose-Fermi mixtures leads to a phase diagram markedly different from pure fermionic or bosonic systems. However, investigating this phase diagram remains challenging when bosons condense due to the resulting fast interspecies loss. Here we report observations consistent with a phase transition from a polaronic to a molecular phase in a density-matched degenerate Bose-Fermi mixture. The condensate fraction, representing the order parameter of the transition, is depleted by interactions, and the build-up of strong correlations results in the emergence of a molecular Fermi gas. The features of the underlying quantum phase transition represent a new phenomenon complementary to the paradigmatic Bose-Einstein condensate/Bardeen-Cooper-Schrieffer crossover observed in Fermi systems. By driving the system through the transition, we produce a sample of sodium-potassium molecules exhibiting a large molecule-frame dipole moment in the quantum-degenerate regime. Tuning interspecies interactions in atomic Bose-Fermi mixtures is shown to drive the system through a quantum phase transition. This enables the generation of heteronuclear molecules in the quantum-degenerate regime.

Automated summary

The interplay of quantum statistics and interactions in atomic Bose-Fermi mixtures results in a phase transition from a polaronic to a molecular phase, leading to the emergence of a molecular Fermi gas. This represents a new phenomenon complementary to the Bose-Einstein condensate/Bardeen-Cooper-Schrieffer crossover observed in Fermi systems. By tuning interspecies interactions, heteronuclear molecules can be generated in the quantum-degenerate regime.