pith. sign in

Bell's Inequalities for Continuous-Variable Systems in Generic Squeezed States

1 Pith paper cite this work. Polarity classification is still indexing.

1 Pith paper citing it
abstract

Bell's inequality for continuous-variable bipartite systems is studied. The inequality is expressed in terms of pseudo-spin operators and quantum expectation values are calculated for generic two-mode squeezed states characterized by a squeezing parameter $r$ and a squeezing angle $\varphi$. Allowing for generic values of the squeezing angle is especially relevant when $\varphi$ is not under experimental control, such as in cosmic inflation, where small quantum fluctuations in the early Universe are responsible for structures formation. Compared to previous studies restricted to $\varphi=0$ and to a fixed orientation of the pseudo-spin operators, allowing for $\varphi\neq 0$ and optimizing the angular configuration leads to a completely new and rich phenomenology. Two dual schemes of approximation are designed that allow for comprehensive exploration of the squeezing parameters space. In particular, it is found that Bell's inequality can be violated when the squeezing parameter $r$ is large enough, $r\gtrsim 1.12$, and the squeezing angle $\varphi$ is small enough, $\varphi\lesssim 0.34\,e^{-r}$.

fields

hep-th 1

years

2026 1

verdicts

UNVERDICTED 1

representative citing papers

Hidden quantum-informatic symmetries of quasi-de Sitter backgrounds

hep-th · 2026-07-01 · unverdicted · novelty 7.0

Wands-dual quasi-de Sitter backgrounds produce identical symplectic eigenvalues in the Gaussian covariance matrix of localized scalar modes, revealing a quantum-informatic symmetry preserved by the duality's canonical transformation properties.

citing papers explorer

Showing 1 of 1 citing paper.

  • Hidden quantum-informatic symmetries of quasi-de Sitter backgrounds hep-th · 2026-07-01 · unverdicted · none · ref 6 · internal anchor

    Wands-dual quasi-de Sitter backgrounds produce identical symplectic eigenvalues in the Gaussian covariance matrix of localized scalar modes, revealing a quantum-informatic symmetry preserved by the duality's canonical transformation properties.