Rydberg-atom-based electrometry

Huang, Wei; Liang, Zhen-Tao; Du, Yan-Xiong; Yan, Hui; Zhu, Shi-Liang

doi:10.7498/aps.64.160702

Cited by 14 publications

(1 citation statement)

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“…Recently, the Rydberg atoms have been demonstrated as electromagnetic field sensors with ultrahigh sensitivity and capability of self-calibration [24][25][26][27][28][29] : the Rydberg-atom sensors have been proved to be excellent quantum receivers for the microwave communications [30][31][32] . In the THz frequency range, the Rydberg atoms still have large dipole moment making them ideal candidates for THz quantum sensors [33][34][35][36] .…”

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confidence: 99%

Terahertz Receiver based on Room-Temperature Rydberg-Atoms

Lin¹,

She²,

Chen³

et al. 2022

Preprint

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Terahertz wireless communications promises to satisfy the future high-capacity demand. However, practical system for terahertz wireless communications faces many challenges. Among them, the communications distance is a crucial problem due to serious propagation loss. Here we demonstrate a 338.7 GHz wireless link based on the cesium Rydberg atoms in a room-temperature vapor cell. The minimum detectable electric field of 132 ± 13µV /cm (9.72 s detection) is realized in our system. With this atomic receiver, the phase-sensitive conversion of amplitude-modulated or frequencymodulated terahertz waves into optical signals is performed to realize the wireless communications with 8-state phaseshift-keying. The experimental results show that the atomic receiver has many advantages due to its quantum properties. Especially, the communications distance has the potential to be over 18 km. Furthermore, the atomic receiver can be used in the terahertz wireless-fiber link to directly convert the wireless signals into optical signals. Our work provide the new path to future terahertz wireless communications.

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confidence: 99%

Terahertz Receiver based on Room-Temperature Rydberg-Atoms

Lin¹,

She²,

Chen³

et al. 2022

Preprint

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Terahertz Receiver based on Room-Temperature Rydberg-Atoms

Lin¹,

Zhen-Yue²,

Chen³

et al. 2023

Fundamental Research

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Rydberg-Atom Terahertz Heterodyne Receiver with Ultrahigh Spectral Resolution

She 佘,

Zhu 祝,

Lin 林

et al. 2024

Chinese Phys. Lett.

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Terahertz heterodyne receivers with high sensitivity and spectral resolution are crucial for various applications. Here, we present a room-temperature atomic terahertz heterodyne receiver that achieves ultrahigh sensitivity and frequency resolution. At a signal frequency of 338.7 GHz, we obtained a sensitivity of 2.88±0.09 µVcm-1Hz-1/2 for electric field measurements. The calibrated linear dynamical range spans approximately 89 dB, ranging from -110 dBV/cm to -21 dBV/cm. We demodulate a 400 symbol stream encoded in 4-state phase-shift keying, demonstrating excellent phase detection capability. By scanning the frequency of the local oscillator, we realized a terahertz spectrometer with Hz level frequency resolution. This resolution is more than two orders of magnitude higher than that of existing terahertz spectrometers. The demonstrated terahertz heterodyne receiver holds promising potential for working across the entire terahertz spectrum, significantly advancing its practical applications.

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Rydberg-atom-based electrometry

Cited by 14 publications

References 50 publications

Terahertz Receiver based on Room-Temperature Rydberg-Atoms

Terahertz Receiver based on Room-Temperature Rydberg-Atoms

Terahertz Receiver based on Room-Temperature Rydberg-Atoms

Rydberg-Atom Terahertz Heterodyne Receiver with Ultrahigh Spectral Resolution

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