Coherence of Rabi oscillations with spin exchange

TL;DR

This paper investigates the coherence of Rabi oscillations in atomic vapor cells, developing a comprehensive model that accounts for non-static populations and verifying it through experiments, enhancing understanding for sensing applications.

Contribution

It introduces a full model for spin-exchange coherence in hyperfine transitions considering non-static populations, validated by experimental data.

Findings

Excellent agreement between theory and experiment

Rabi oscillations show nontrivial time-domain signals

Model aids in benchmarking Rabi measurement sensitivities

Abstract

Rabi measurements in atomic vapor cells are of current interest in a range of microwave imaging and sensing experiments, but are increasingly in a parameter space outside of theoretical studies of coherence defined by spin-exchange collisions. Here, we study the coherence of Rabi oscillations in vapor cells by employing continuous non-destructive readout of the hyperfine manifold of $^{87}$Rb using Faraday rotation. We develop a full model for spin-exchange (SE) coherence for hyperfine transitions that takes into account a non-static population distribution. In this regime, Rabi oscillations exhibit nontrivial time-domain signals that allow verification of vapor-cell parameters. We find excellent agreement between theory and experiment, which will aid in benchmarking sensitivities of Rabi measurement applications.