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Open Quantum Systems Decoherence
Nonlocal Entanglement and Directional Correlations of Primordial Perturbations on the Inflationary Horizon
arXiv
Authors: Craig Hogan
Year
2018
Paper ID
23489
Status
Preprint
Abstract Read
~2 min
Abstract Words
122
Citations
N/A
Abstract
Models are developed to estimate properties of relic cosmic perturbations with "spooky" nonlocal correlations on the inflationary horizon, analogous to those previously posited for information on black hole event horizons. Scalar curvature perturbations are estimated to emerge with a dimensionless power spectral density ΔS2approx H tP, the product of inflationary expansion rate H with Planck time tP, larger than standard inflaton fluctuations. Current measurements of the spectrum are used to derive constraints on parameters of the effective potential in a slow-roll background. It is shown that spooky nonlocality can create statistically homogeneous and isotropic primordial curvature perturbations that are initially directionally antisymmetric. New statistical estimators are developed to study unique signatures in CMB anisotropy and large scale galaxy surveys.
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- This paper contributes to the Open Quantum Systems & Decoherence research area in the Quantum Articles archive.
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- Models are developed to estimate properties of relic cosmic perturbations with "spooky" nonlocal correlations on the inflationary horizon, analogous to those previously posited...
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