Chemical Reaction of Ultracold Atoms and Ions in a Hybrid Trap

Abstract

Interactions between cold ions and atoms have been proposed for use in implementing quantum gatesIdziaszek2007, probing quantum gasesSherkunov2009, observing novel charge-transport dynamicsCote2000, and sympathetically cooling atomic and molecular systems which cannot be laser cooledSmith2005,Hudson2009. Furthermore, the chemistry between cold ions and atoms is foundational to issues in modern astrophysics, including the formation of stars, planets, and interstellar cloudsSmith1992, the diffuse interstellar bandsReddy2010, and the post-recombination epoch of the early universeStancil1996b. However, as pointed out in refs 9 and 10, both experimental data and a theoretical description of the ion-atom interaction at low temperatures, reached in these modern atomic physics experiments and the interstellar environment, are still largely missing. Here we observe a chemical reaction between ultracold 174Yb+ ions and 40Ca atoms held in a hybrid trap. We measure, and theoretically reproduce, a chemical reaction rate constant of K =(21.3)×10-10 cm3s-1 for 1 mK ≤ T ≤ 10 K, four orders of magnitude higher than reported for other heteronuclear cases. We also offer a possible explanation for the apparent contradiction between typical theoretical predictions and measurements of the radiative association process in this and other systems.