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Determining the angle-of-arrival of a radio-frequency source with a Rydberg atom-based sensor

Amy K. Robinson, Nikunjkumar Prajapati, Damir Senić, Matthew T. Simons, Christopher L. Holloway

2021Applied Physics Letters157 citationsDOIOpen Access PDF

Abstract

In this work, we demonstrate the use of a Rydberg atom-based sensor for determining the angle of arrival of an incident radio frequency (RF) wave or signal. The technique uses electromagnetically induced transparency in Rydberg atomic vapor in conjunction with a heterodyne Rydberg atom-based mixer. The Rydberg atom mixer measures the phase of the incident RF wave at two different locations inside an atomic vapor cell. The phase difference at these two locations is related to the direction of arrival of the incident RF wave. To demonstrate this approach, we measure phase differences of an incident 19.18 GHz wave at two locations inside a vapor cell filled with cesium atoms for various incident angles. Comparisons of these measurements with both the full-wave simulation and the plane wave theoretical model show that these atom-based sub-wavelength phase measurements can be used to determine the angle of arrival of an RF field.

Topics & Concepts

Electromagnetically induced transparencyRydberg atomAtomic physicsRadio frequencyPhysicsRydberg formulaAtom (system on chip)Plane wavePhase (matter)Angle of arrivalTime of arrivalHeterodyne detectionOpticsLaserTelecommunicationsIonizationChannel (broadcasting)Embedded systemQuantum mechanicsComputer scienceIonAntenna (radio)Cold Atom Physics and Bose-Einstein CondensatesQuantum optics and atomic interactionsAtomic and Subatomic Physics Research