Paul D. Kunz scite author profile

Rydberg atoms, with one highly-excited, nearly-ionized electron, have extreme sensitivity to electric fields, including microwave fields ranging from 100 MHz to over 1 THz. Here we show that room-temperature Rydberg atoms can be used as sensitive, high bandwidth, microwave communication antennas. We demonstrate near photon-shot-noise limited readout of data encoded in amplitude-modulated 17 GHz microwaves, using an electromagnetically-induced-transparency (EIT) probing scheme. We measure a photon-shot-noise limited channel capacity of up to 8.2 Mbit s −1 and implement an 8-state phase-shift-keying digital communication protocol. The bandwidth of the EIT probing scheme is found to be limited by the available coupling laser power and the natural linewidth of the rubidium D2 transition. We discuss how atomic communications receivers offer several opportunities to surpass the capabilities of classical antennas.

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Quantum-Limited Atomic Receiver in the Electrically Small Regime

Cox

et al. 2018

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We use a quantum sensor based on thermal Rydberg atoms to receive data encoded in electromagnetic fields in the extreme electrically small regime, with a sensing volume over 10^{7} times smaller than the cube of the electric field wavelength. We introduce the standard quantum limit for data capacity, and experimentally observe quantum-limited data reception for bandwidths from 10 kHz up to 30 MHz. In doing this, we provide a useful alternative to classical communication antennas, which become increasingly ineffective when the size of the antenna is significantly smaller than the wavelength of the electromagnetic field.

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Assessment of Rydberg atoms for wideband electric field sensing

Meyer

Castillo

Cox

et al. 2020

J. Phys. B: At. Mol. Opt. Phys.

105

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Rydberg atoms have attracted significant interest recently as electric field sensors. In order to assess potential applications, detailed understanding of relevant figures of merit is necessary, particularly in relation to other, more mature, sensor technologies. Here we present a quantitative analysis of the Rydberg sensor's sensitivity to oscillating electric fields with frequencies between 1 kHz and 1 THz. Sensitivity is calculated using a combination of analytical and semi-classical Floquet models. Using these models, optimal sensitivity at arbitrary field frequency is determined. We validate the numeric Floquet model via experimental Rydberg sensor measurements over a range of 1-20 GHz. Using analytical models, we compare with two prominent electric field sensor technologies: electro-optic crystals and dipole antenna-coupled passive electronics.

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Waveguide-Coupled Rydberg Spectrum Analyzer from 0 to 20 GHz

2021

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Optimal atomic quantum sensing using electromagnetically-induced-transparency readout

et al. 2021

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Paul D. Kunz

Digital communication with Rydberg atoms and amplitude-modulated microwave fields

Quantum-Limited Atomic Receiver in the Electrically Small Regime

Assessment of Rydberg atoms for wideband electric field sensing

Waveguide-Coupled Rydberg Spectrum Analyzer from 0 to 20 GHz

Optimal atomic quantum sensing using electromagnetically-induced-transparency readout

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