Fermionic suppression of dipolar relaxation: Observation of universal inelastic dipolar scattering

TL;DR

This study demonstrates that quantum statistics suppress inelastic dipolar scattering in ultracold fermionic dysprosium gases, confirming theoretical predictions and enabling more stable quantum many-body experiments with dipolar atoms or molecules.

Contribution

First experimental confirmation of universal inelastic dipolar scattering suppression in fermionic dysprosium, aligning with theoretical predictions and enabling advanced quantum physics research.

Findings

120-fold suppression of dipolar relaxation in fermionic vs. bosonic Dy

Low inelastic cross sections in spin mixtures match universal scattering theory

Suppression enhances stability for quantum many-body experiments with dipolar gases

Abstract

We observe the suppression of inelastic dipolar scattering in ultracold Fermi gases of the highly magnetic atom dysprosium: the more energy that is released, the less frequently these exothermic reactions take place, and only quantum spin statistics can explain this counterintuitive effect. Inelastic dipolar scattering in non-zero magnetic fields leads to heating or to loss of the trapped population, both detrimental to experiments intended to study quantum many-body physics with strongly dipolar gases. Fermi statistics, however, is predicted to lead to a kinematic suppression of these harmful reactions. Indeed, we observe a 120-fold suppression of dipolar relaxation in fermionic versus bosonic Dy, as expected from theory describing universal inelastic dipolar scattering, though never before experimentally confirmed. Similarly low inelastic cross sections are observed in spin mixtures, also with striking correspondence to universal dipolar scattering predictions. The suppression of relaxation opens the possibility of employing fermionic dipolar species---atoms or molecules---in studies of quantum many-body physics involving, e.g., synthetic gauge fields and pairing.