Transient Phase Sensing in a Three-Photon Rydberg Ladder Scheme

TL;DR

This paper demonstrates a novel all-optical method for transient phase sensing of RF signals using a three-photon Rydberg ladder scheme in Cesium vapor, enabling detection of phase shifts and Doppler effects without closed-loop interferometry.

Contribution

It introduces a room-temperature, all-optical RF phase sensing technique based on a three-photon Rydberg ladder scheme, which is sensitive to transient phase changes and Doppler shifts.

Findings

All-optical RF phase sensing achieved in Cesium vapor.

Detection of RF phase shifts and Doppler shifts demonstrated.

Potential application in radar for target detection and velocity measurement.

Abstract

Although Rydberg atoms have shown promise for use in novel types of radio frequency receivers, they have generally not been considered phase sensitive without the use of closed-loop interferometry or auxiliary radio frequency fields. Here, we show that the high coherency of a narrow-linewidth three-photon ladder excitation scheme unique to Cesium atoms enables all-optical sensing of transient changes in RF phase within a room temperature vapor cell. The transient response on the probe laser's transmission originates from phase-to-amplitude conversion via a disturbance of the coherency of the system in response to the phase shift of the radio frequency field. We show that the amplitude and frequency of the oscillatory response provides information on the magnitude and direction of any radio frequency field detuning. We demonstrate that the detuning sensitivity can be used to identify Doppler shifts in radar applications, by applying phase shifts embedded in radio frequency pulses. The phase modulation within the radar pulse acts as a form of compression that facilitates the simultaneous detection of both target position and velocity.