Millikelvin Reactive Collisions between Sympathetically-Cooled Molecular Ions and Laser-Cooled Atoms in an Ion-Atom Hybrid Trap

TL;DR

This study investigates ultracold reactive collisions between molecular ions and laser-cooled atoms at millikelvin temperatures, revealing energy-independent reaction rates and enhanced charge exchange with excited Rb states, testing classical reaction models.

Contribution

It demonstrates reaction dynamics at unprecedented low energies and highlights the influence of atomic internal states on reaction rates in ion-atom collisions.

Findings

Reaction rates are independent of collision energy below 20 mK.

Charge exchange is four times faster with excited Rb (5p) state.

Results support classical capture models dominated by charge-quadrupole interactions.

Abstract

We report on a study of cold reactive collisions between sympathetically-cooled molecular ions and laser-cooled atoms in an ion-atom hybrid trap. Chemical reactions were studied at average collision energies <Ecoll>/k > 20 mK, about two orders of magnitude lower than has been achieved in previous experiments with molecular ions. Choosing N2+ +Rb as a prototypical system, we find that the reaction rate is independent of the collision energy, but strongly dependent on the internal state of Rb. Highly efficient charge exchange about four times faster than the Langevin rate was observed with Rb in the excited (5p) 2P3/2 state. This observation is rationalized in terms of a capture process dominated by the charge- quadrupole interaction and a near resonance between the entrance and exit channels of the reaction. Our results provide a test of classical models for reactions of molecular ions at the lowest energies reached thus far.