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Main Authors: Kaur, Channprit, Shen, Pinrui, Booth, Donald, Todd, Andrew, Shaffer, James P.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.17506
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author Kaur, Channprit
Shen, Pinrui
Booth, Donald
Todd, Andrew
Shaffer, James P.
author_facet Kaur, Channprit
Shen, Pinrui
Booth, Donald
Todd, Andrew
Shaffer, James P.
contents Rydberg atom radio frequency sensors are unique in a number of ways, including possessing extraordinary carrier bandwidth, self-calibration and accuracy. In this paper, we examine the impact of thermal radiation on Rydberg atom sensors. Antennas are limited by their thermal background, while Rydberg atom sensors are coherent sensors. Incoherent thermal radiation does not limit Rydberg atom sensors in the same way as an antenna. The primary consequence of a thermal radiation field on Rydberg atom sensors is to decrease their coherence, as the decay rates of the Rydberg states used for sensing the radio frequency field are increased due to the thermal field, i.e. blackbody, modification of the atomic decay rates. Thermal and coherent field excitation are fundamentally different in that thermal fields produce statistically independent excitations with well-defined frequency, polarization, and propagation direction, while coherent states are coherent superpositions of photon number states. Consequently, thermal fields do not contribute to the coherences of the density matrix that are used for Rydberg atom sensing, except for damping them.
format Preprint
id arxiv_https___arxiv_org_abs_2508_17506
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The Impact of Thermal Fields on Rydberg Atom Radio Frequency Sensors
Kaur, Channprit
Shen, Pinrui
Booth, Donald
Todd, Andrew
Shaffer, James P.
Atomic Physics
Rydberg atom radio frequency sensors are unique in a number of ways, including possessing extraordinary carrier bandwidth, self-calibration and accuracy. In this paper, we examine the impact of thermal radiation on Rydberg atom sensors. Antennas are limited by their thermal background, while Rydberg atom sensors are coherent sensors. Incoherent thermal radiation does not limit Rydberg atom sensors in the same way as an antenna. The primary consequence of a thermal radiation field on Rydberg atom sensors is to decrease their coherence, as the decay rates of the Rydberg states used for sensing the radio frequency field are increased due to the thermal field, i.e. blackbody, modification of the atomic decay rates. Thermal and coherent field excitation are fundamentally different in that thermal fields produce statistically independent excitations with well-defined frequency, polarization, and propagation direction, while coherent states are coherent superpositions of photon number states. Consequently, thermal fields do not contribute to the coherences of the density matrix that are used for Rydberg atom sensing, except for damping them.
title The Impact of Thermal Fields on Rydberg Atom Radio Frequency Sensors
topic Atomic Physics
url https://arxiv.org/abs/2508.17506