Randomness-based macroscopic Franson-type nonlocal correlation
Abstract
Franson-type nonlocal correlation is a testing tool for Bell inequality violation using noninterfering interferometers, where coincidence measurements involve an interference fringe of g^((1)) correlation between noninterfering photon pairs. Like the Bell inequality, Franson correlation is also limited to a microscopic regime of entangled photon pairs. Here, randomness-based macroscopic Franson-type nonlocal correlation is presented using polarization-basis coherent superposition of laser light, where probabilistic randomness between bipartite orthonormal bases plays an important role for both Bell inequality and the g^((1)) correlation. Without contradiction to the conventional understanding of quantumness limited by the particle nature of photons, the proposed Franson correlation can also be extended to a general scheme of macroscopic regimes via coherent superposition.
Cite
@article{arxiv.2101.06463,
title = {Randomness-based macroscopic Franson-type nonlocal correlation},
author = {B. S. Ham},
journal= {arXiv preprint arXiv:2101.06463},
year = {2021}
}
Comments
7 pages, 2 figures