Spin-orbit interactions and quantum spin dynamics in cold ion-atom collisions

TL;DR

This study uses ab initio and quantum scattering calculations to identify spin-orbit interactions as the main cause of hyperfine relaxation in cold Yb$^+$-Rb collisions, with implications for quantum technologies.

Contribution

It provides the first detailed analysis of spin-orbit effects in Yb$^+$-Rb collisions, highlighting their impact on hyperfine relaxation and decoherence.

Findings

Spin-orbit interaction dominates hyperfine relaxation.

Calculated relaxation rates are four times lower than Langevin theory predictions.

Rates show a weak temperature dependence, indicating non-statistical behavior.

Abstract

We present accurate ab initio and quantum scattering calculations on a prototypical hybrid ion-atom system Yb$^+$-Rb, recently suggested as a promising candidate for the experimental study of open quantum systems, quantum information processing, and quantum simulation. We identify the second-oder spin-orbit (SO) interaction as the dominant source of hyperfine relaxation and decoherence in cold Yb$^+$-Rb collisions. Our results are in good agreement with recent experimental observations [L. Ratschbacher et al., Phys. Rev. Lett. 110, 160402 (2013)] of hyperfine relaxation rates of trapped Yb$^+$ immersed in an ultracold Rb gas. The calculated rates are 4 times smaller than predicted by the Langevin capture theory and display a weak $T^{-0.3}$ temperature dependence, indicating significant deviations from statistical behavior. Our analysis underscores the deleterious nature of the SO interaction and implies that light ion-atom combinations such as Yb$^+$-Li should be used to minimize hyperfine relaxation and decoherence of trapped ions in ultracold atomic gases.