New Journal of Physics (Jan 2013)

Detecting high-density ultracold molecules using atom–molecule collision

  • Jun-Ren Chen,
  • Cheng-Yang Kao,
  • Hung-Bin Chen,
  • Yi-Wei Liu

DOI
https://doi.org/10.1088/1367-2630/15/4/043035
Journal volume & issue
Vol. 15, no. 4
p. 043035

Abstract

Read online

Utilizing single-photon photoassociation, we have achieved ultracold rubidium molecules with a high number density that provides a new efficient approach toward molecular quantum degeneracy. A new detection mechanism for ultracold molecules utilizing inelastic atom–molecule collision is demonstrated. The resonant coupling effect on the formation of the X ^1 Σ ^+ _g ground state ^85 Rb _2 allows for a sufficient number of more deeply bound ultracold molecules, which induced an additional trap loss and heating of the co-existing atoms owing to the inelastic atom–molecule collision. Therefore, after the photoassociation process, the ultracold molecules can be investigated using the absorption image of the ultracold rubidium atoms mixed with the molecules in a crossed optical dipole trap. The existence of the ultracold molecules was then verified, and the amount of accumulated molecules was measured. This method detects the final produced ultracold molecules, and hence is distinct from the conventional trap loss experiment, which is used to study the association resonance. It is composed of measurements of the time evolution of an atomic cloud and a decay model, by which the number density of the ultracold ^85 Rb _2 molecules in the optical trap was estimated to be >5.2 × 10 ^11 cm ^−3 .