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Distinguishability in quantum interference with the squeezed states

Quantum Physics 2022-06-03 v4 Mathematical Physics math.MP

Abstract

Distinguishability theory is developed for quantum interference of the squeezed vacuum states on unitary linear interferometers. It is found that the entanglement of photon pairs over the Schmidt modes is one of the sources of distinguishability. The distinguishability is quantified by the symmetric part of the internal state of nn pairs of photons, whose normalization q2nq_{2n} is the probability that 2n2n photons interfere as indistinguishable. For two pairs of photons q4=(1+2P)/3q_{4}=(1+ 2\mathbb{P} )/3, where P\mathbb{P} is the purity of the squeezed states (K=1/PK=1/\mathbb{P} is the Schmidt number). For a fixed purity P\mathbb{P}, the probability q2nq_{2n} decreases exponentially fast in nn. For example, in the experimental Gaussian boson sampling of H.-S.~Zhong \textit{et al} [Science \textbf{370}, 1460 (2020)], the achieved purity P0.938\mathbb{P}\approx 0.938 for the average number of photons 2n432n\ge 43 gives q2n0.5q_{2n}\lesssim 0.5, i.e., close to the middle line between nn indistinguishable and nn distinguishable pairs of photons. In derivation of all the results the first-order quantization representation based on the particle decomposition of the Hilbert space of identical bosons serves as an indispensable tool. The approach can be applied also to the generalized (non-Gaussian) squeezed states, such as those recently generated in the three-photon parametric down-conversion.

Keywords

Cite

@article{arxiv.2109.01857,
  title  = {Distinguishability in quantum interference with the squeezed states},
  author = {Valery Shchesnovich},
  journal= {arXiv preprint arXiv:2109.01857},
  year   = {2022}
}

Comments

21 pages, 2 figures; In the last revision: Subsection IIA is added with mathematical details of the approach used. Typo in Eq. (62) is corrected. New Eqs. (21), (23) (24) and (47) are added. DOI added

R2 v1 2026-06-24T05:40:53.472Z