Enhancement of the formation of ultracold 85Rb2 molecules due to resonant coupling

Abstract

We have studied the effect of resonant electronic state coupling on the formation of ultracold ground-state 85Rb2. Ultracold Rb2 molecules are formed by photoassociation (PA) to a coupled pair of 0u+ states, 0u+(P1/2) and 0u+(P3/2), in the region below the 5S+5P1/2 limit. Subsequent radiative decay produces high vibrational levels of the ground state, X 1g+. The population distribution of these X state vibrational levels is monitored by resonance-enhanced two-photon ionization through the 2 1u+ state. We find that the populations of vibrational levels v''=112-116 are far larger than can be accounted for by the Franck-Condon factors for 0u+(P1/2) X 1g+ transitions with the 0u+(P1/2) state treated as a single channel. Further, the ground-state molecule population exhibits oscillatory behavior as the PA laser is tuned through a succession of 0u+ state vibrational levels. Both of these effects are explained by a new calculation of transition amplitudes that includes the resonant character of the spin-orbit coupling of the two 0u+ states. The resulting enhancement of more deeply bound ground-state molecule formation will be useful for future experiments on ultracold molecules.