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Experimental demonstrations for randomness-based macroscopic Franson-type nonlocal correlation using coherently coupled photons

Quantum Physics 2021-07-02 v1

Abstract

Franson-type nonlocal quantum correlation based on the particle nature of quantum mechanics has been intensively studied for both fundamental physics and potential applications of quantum key distribution between remotely separated parties over the last several decades. Recently, a coherence theory of deterministic quantum features has been applied for Franson-type nonlocal correlation [arXiv:2102.06463] to understand its quantumness in a purely classical manner, where the resulting features are deterministic and macroscopic. Here, nearly sub-Poisson distributed coherent photon pairs obtained from an attenuated laser are used for the experimental demonstrations of the coherence Franson-type nonlocal correlation. As an essential requirement of quantum mechanics, quantum superposition is macroscopically provided using polarization basis-randomness via a half-wave plate, satisfying fairness compared with the original scheme based on phase bases. The observed coherence quantum feature of the modified Franson correlation successfully demonstrates the proposed wave nature of quantum mechanics, where the unveiled nonlocal correlation is relied on a definite phase relation between the paired coherent photons.

Keywords

Cite

@article{arxiv.2107.00302,
  title  = {Experimental demonstrations for randomness-based macroscopic Franson-type nonlocal correlation using coherently coupled photons},
  author = {S. Kim and B. S. Ham},
  journal= {arXiv preprint arXiv:2107.00302},
  year   = {2021}
}

Comments

9 pages, 3 figures, 1 table

R2 v1 2026-06-24T03:47:48.496Z