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Main Author: Shih, Yanhua
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.06669
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author Shih, Yanhua
author_facet Shih, Yanhua
contents This letter reports on the study of entangled laser beams, or entangled coherent states, from their generation to their nonlocal coherent behavior. Although in continuous wave operation, the entangled laser beams are able to produce comb-like correlation with 100\% contrast in distant joint photodetection. We name this comb-function quantum ghost frequency comb (QGFC). What is the cause of these periodic sharp correlations? Can we trust zero-coincidences, or anti-correlation, in the joint measurement of CW laser beams? Besides its fundamental interests, bright QGFCs make important contributions to the fields of nonlocal precision spectroscopy, positioning, and time transfer. Superior to entangled photon pairs, measurements of entangled laser beams do not rely on photon counting and can be performed over greater distance in shorter time with higher resolution and accuracy.
format Preprint
id arxiv_https___arxiv_org_abs_2505_06669
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Entangled laser beams and quantum ghost frequency comb
Shih, Yanhua
Quantum Physics
This letter reports on the study of entangled laser beams, or entangled coherent states, from their generation to their nonlocal coherent behavior. Although in continuous wave operation, the entangled laser beams are able to produce comb-like correlation with 100\% contrast in distant joint photodetection. We name this comb-function quantum ghost frequency comb (QGFC). What is the cause of these periodic sharp correlations? Can we trust zero-coincidences, or anti-correlation, in the joint measurement of CW laser beams? Besides its fundamental interests, bright QGFCs make important contributions to the fields of nonlocal precision spectroscopy, positioning, and time transfer. Superior to entangled photon pairs, measurements of entangled laser beams do not rely on photon counting and can be performed over greater distance in shorter time with higher resolution and accuracy.
title Entangled laser beams and quantum ghost frequency comb
topic Quantum Physics
url https://arxiv.org/abs/2505.06669