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Main Authors: Shen, Kang, Hu, Xiangming, Wang, Fei
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.23110
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author Shen, Kang
Hu, Xiangming
Wang, Fei
author_facet Shen, Kang
Hu, Xiangming
Wang, Fei
contents Multiensemble superradiance extends Dicke superradiance to multiple ensembles and supports dark states whose properties depend on the initial state. In the large-\(N\) limit, we derive analytical covariance matrices for these dark states, revealing inter-ensemble entanglement that enhances quantum metrology. The minimum eigenvalue, determined by the curvature of the superradiance potential, corresponds to the optimal multiparameter spin-squeezing coefficient, which is given by the \emph{Rayleigh quotient} of the spin-squeezing matrix, linking metrological sensitivity to the geometric structure of the underlying dynamics. The multiparameter squeezing coefficient provides a variational framework for optimizing metrological performance. These results enable optimal estimation of arbitrary linear combinations of multiple parameters, offering a concrete protocol for distributed quantum sensing and a promising route toward multimode quantum interferometry.
format Preprint
id arxiv_https___arxiv_org_abs_2510_23110
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Multiensemble Superradiance for Distributed Quantum Sensing
Shen, Kang
Hu, Xiangming
Wang, Fei
Quantum Physics
Multiensemble superradiance extends Dicke superradiance to multiple ensembles and supports dark states whose properties depend on the initial state. In the large-\(N\) limit, we derive analytical covariance matrices for these dark states, revealing inter-ensemble entanglement that enhances quantum metrology. The minimum eigenvalue, determined by the curvature of the superradiance potential, corresponds to the optimal multiparameter spin-squeezing coefficient, which is given by the \emph{Rayleigh quotient} of the spin-squeezing matrix, linking metrological sensitivity to the geometric structure of the underlying dynamics. The multiparameter squeezing coefficient provides a variational framework for optimizing metrological performance. These results enable optimal estimation of arbitrary linear combinations of multiple parameters, offering a concrete protocol for distributed quantum sensing and a promising route toward multimode quantum interferometry.
title Multiensemble Superradiance for Distributed Quantum Sensing
topic Quantum Physics
url https://arxiv.org/abs/2510.23110