Atom-Based Sensing of Weak Radio Frequency Electric Fields Using Homodyne Readout

Santosh Kumar; Haoquan Fan; Harald Kübler; Jiteng Sheng; James P. Shaffer

doi:10.1038/srep42981

Atom-Based Sensing of Weak Radio Frequency Electric Fields Using Homodyne Readout

Santosh Kumar
, Haoquan Fan
, Harald Kübler
, Jiteng Sheng
, James P. Shaffer

Department of Physics

Research output: Contribution to journal › Article › peer-review

174 Scopus citations

Abstract

We utilize a homodyne detection technique to achieve a new sensitivity limit for atom-based, absolute radio-frequency electric field sensing of 5 μV cm^-1 Hz^1/2. A Mach-Zehnder interferometer is used for the homodyne detection. With the increased sensitivity, we investigate the dominant dephasing mechanisms that affect the performance of the sensor. In particular, we present data on power broadening, collisional broadening and transit time broadening. Our results are compared to density matrix calculations. We show that photon shot noise in the signal readout is currently a limiting factor. We suggest that new approaches with superior readout with respect to photon shot noise are needed to increase the sensitivity further.

Original language	English
Article number	42981
Journal	Scientific Reports
Volume	7
DOIs	https://doi.org/10.1038/srep42981
State	Published - 20 Feb 2017

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title = "Atom-Based Sensing of Weak Radio Frequency Electric Fields Using Homodyne Readout",

abstract = "We utilize a homodyne detection technique to achieve a new sensitivity limit for atom-based, absolute radio-frequency electric field sensing of 5 μV cm-1 Hz1/2. A Mach-Zehnder interferometer is used for the homodyne detection. With the increased sensitivity, we investigate the dominant dephasing mechanisms that affect the performance of the sensor. In particular, we present data on power broadening, collisional broadening and transit time broadening. Our results are compared to density matrix calculations. We show that photon shot noise in the signal readout is currently a limiting factor. We suggest that new approaches with superior readout with respect to photon shot noise are needed to increase the sensitivity further.",

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AU - Kumar, Santosh

AU - Fan, Haoquan

AU - Kübler, Harald

AU - Sheng, Jiteng

AU - Shaffer, James P.

PY - 2017/2/20

Y1 - 2017/2/20

N2 - We utilize a homodyne detection technique to achieve a new sensitivity limit for atom-based, absolute radio-frequency electric field sensing of 5 μV cm-1 Hz1/2. A Mach-Zehnder interferometer is used for the homodyne detection. With the increased sensitivity, we investigate the dominant dephasing mechanisms that affect the performance of the sensor. In particular, we present data on power broadening, collisional broadening and transit time broadening. Our results are compared to density matrix calculations. We show that photon shot noise in the signal readout is currently a limiting factor. We suggest that new approaches with superior readout with respect to photon shot noise are needed to increase the sensitivity further.

AB - We utilize a homodyne detection technique to achieve a new sensitivity limit for atom-based, absolute radio-frequency electric field sensing of 5 μV cm-1 Hz1/2. A Mach-Zehnder interferometer is used for the homodyne detection. With the increased sensitivity, we investigate the dominant dephasing mechanisms that affect the performance of the sensor. In particular, we present data on power broadening, collisional broadening and transit time broadening. Our results are compared to density matrix calculations. We show that photon shot noise in the signal readout is currently a limiting factor. We suggest that new approaches with superior readout with respect to photon shot noise are needed to increase the sensitivity further.

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VL - 7

JO - Scientific Reports

JF - Scientific Reports

M1 - 42981

ER -

Atom-Based Sensing of Weak Radio Frequency Electric Fields Using Homodyne Readout

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