Optical sensing near the quantum limit with enhanced dynamic range by resolving the spectra of interfering photons

Russell M.J. Brooks; Luca Maggio; Thomas Jaeken; Joseph Ho; Erik M. Gauger; Vincenzo Tamma; Alessandro Fedrizzi

doi:10.1103/6xy6-c2yd

Optical sensing near the quantum limit with enhanced dynamic range by resolving the spectra of interfering photons

Russell M.J. Brooks
, Luca Maggio
, Thomas Jaeken
, Joseph Ho
, Erik M. Gauger
, Vincenzo Tamma
, Alessandro Fedrizzi^*

^*Corresponding author for this work

School of Mathematics & Physics

Heriot-Watt University

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

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Abstract

Optical sensing schemes based on two-photon interference offer a powerful platform for precision metrology, but are usually limited by a trade-off between dynamic range and measurement precision. Here, we overcome this limitation by resolving the frequency of two photons impinging on a beam splitter and combining these measurements with a new estimation strategy. This increases the usable dynamic range by up to a factor of 20 compared with conventional frequency nonresolved schemes. We implement the method with independent photon pair sources and characterize its performance in the presence of finite-resolution frequency-resolved detectors, which approach the quantum limit in the lossless regime. Our approach enables scan-free, nanometer resolution depth sensing over millimeter scale distances, with potential applications in biological and nanomaterial imaging.

Original language	English
Article number	060803
Number of pages	7
Journal	Physical Review Letters
Volume	136
Issue number	6
DOIs	https://doi.org/10.1103/6xy6-c2yd
Publication status	Published - 13 Feb 2026

Keywords

UKRI
EPSRC
EP/T001011/1

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Optical sensing near the quantum limitFinal published version, 925 KBLicence: CC BY

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title = "Optical sensing near the quantum limit with enhanced dynamic range by resolving the spectra of interfering photons",

abstract = "Optical sensing schemes based on two-photon interference offer a powerful platform for precision metrology, but are usually limited by a trade-off between dynamic range and measurement precision. Here, we overcome this limitation by resolving the frequency of two photons impinging on a beam splitter and combining these measurements with a new estimation strategy. This increases the usable dynamic range by up to a factor of 20 compared with conventional frequency nonresolved schemes. We implement the method with independent photon pair sources and characterize its performance in the presence of finite-resolution frequency-resolved detectors, which approach the quantum limit in the lossless regime. Our approach enables scan-free, nanometer resolution depth sensing over millimeter scale distances, with potential applications in biological and nanomaterial imaging.",

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AU - Brooks, Russell M.J.

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AU - Gauger, Erik M.

AU - Tamma, Vincenzo

AU - Fedrizzi, Alessandro

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AB - Optical sensing schemes based on two-photon interference offer a powerful platform for precision metrology, but are usually limited by a trade-off between dynamic range and measurement precision. Here, we overcome this limitation by resolving the frequency of two photons impinging on a beam splitter and combining these measurements with a new estimation strategy. This increases the usable dynamic range by up to a factor of 20 compared with conventional frequency nonresolved schemes. We implement the method with independent photon pair sources and characterize its performance in the presence of finite-resolution frequency-resolved detectors, which approach the quantum limit in the lossless regime. Our approach enables scan-free, nanometer resolution depth sensing over millimeter scale distances, with potential applications in biological and nanomaterial imaging.

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Optical sensing near the quantum limit with enhanced dynamic range by resolving the spectra of interfering photons

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