Trapped ion-mediated interactions between two distant trapped atoms

TL;DR

This paper demonstrates theoretically that ion-mediated interactions between distant trapped atoms can surpass direct interactions, with implications for quantum computing and molecular physics using ion-atom hybrid systems.

Contribution

It introduces a theoretical framework for ion-mediated interactions between separated atoms via Rydberg excitation, highlighting their strength and phonon mode characteristics.

Findings

Ion-mediated interactions exceed direct atom-atom interactions by several orders of magnitude.

Phonon modes are nearly degenerate when both atoms are Rydberg excited.

Non-adiabatic effects induce a gauge structure and geometric phase.

Abstract

We theoretically show that when two largely separated trapped atoms interact with a trapped ion via Rydberg excitation of the atoms, the ion-mediated interaction between the atoms exceeds the direct atom-atom interaction by several orders of magnitude. Since the motion of the atoms is much slower than the motion of the ion, we resort to Born-Oppenheimer approximation to calculate the ion-mediated adiabatic potential. We also calculate the ion-mediated phonon modes of the atoms that are separated by more than 10 micron. For cylindrical geometry of the system and both the atoms being excited to the same Rydberg state, the stretched and center-of-mass (COM) axial or transverse phonon modes are found to be almost degenerate, while the phonon modes are non-degenerate when one atom is in a Rydberg state and the other in the ground state. We discuss the non-adiabatic effects in the system that give rise to a Gauge structure and associated geometric phase in the system. This study may open a new perspective in quantum computing and exploring molecular physics associated with a conical intersection using an ion-atom hybrid architecture.