High-Fidelity Microwave-Polarization Control in a Rydberg-Ensemble Experiment

TL;DR

This paper demonstrates a high-fidelity microwave polarization control system in a Rydberg-ensemble experiment, achieving over 99% fidelity and enabling advanced atomic physics manipulations.

Contribution

It introduces a novel microwave control method using in-vacuum electrodes with independent phase and amplitude control, enhancing polarization fidelity in atomic experiments.

Findings

Achieved >99% fidelity in generating specific microwave polarizations.

Extended polarization purification techniques to off-resonance frequencies.

Enabled precise control of microwave-induced atomic interactions.

Abstract

Control of the polarization of microwave fields is a key experimental capability for a number of atomic physics platforms. However, producing high-fidelity microwaves requires a well-controlled microwave environment, where reflections that distort the polarization must be avoided or well characterized, a constraint that often conflicts with other experimental design considerations. Here we demonstrate a microwave control system capable of producing high-fidelity microwave polarizations in a Rydberg-ensemble experiment. We use three in-vacuum DC electrodes, repurposed as microwave antennae, to produce imperfect and initially unknown polarizations. Each source is driven with independent phase and amplitude control to generate the desired microwave fields. We probe the fields produced at the position of the atoms using Rydberg-EIT spectroscopy of the microwave-induced avoided crossings. We produce $\sigma_-$, $\pi$, and $\sigma_+$ polarized microwaves with > 99 % fidelity and generate their combinations. We extend our purification techniques to frequencies away from Rydberg resonances by utilizing an auxiliary microwave field, generating two-photon microwave resonances. The techniques developed here will facilitate the engineering of dipolar interactions in atomic and molecular physics experiments.