Quantum entanglement arises in the Quarkbase Cosmology framework as a collective excitation of a frictionless etheric plasma—the Ψ-field—rather than as a mysterious nonlocal interaction between isolated particles. Entangled pairs correspond to correlated Ψ-modes created jointly at the source, forming a single extended field excitation with support in two spatial regions. Measurement acts as a local projection on this global structure, producing the strong correlations observed experimentally without requiring superluminal signalling. The theory reproduces standard quantum predictions for Bell states, CHSH violation, and coincidence probabilities, while adding physical scale through the parameters of the etheric plasma (density ρₚ, compressibility K, and screening length λ = 1/mΨ). A decisive prediction emerges: if the vacuum has finite screening, Bell visibility must attenuate as V(r) ∝ e⁻ʳ/λ. Existing long-distance experiments impose strong lower bounds on λ, consistent with a highly coherent vacuum. This paper unifies quantum behaviour with medium dynamics and converts the “mysteries” of collapse and nonlocality into experimentally testable properties of a physical vacuum.
Date: Oct 15, 2025
Author: Carlos Omeñaca Prado
ORCID: https://orcid.org/0009-0001-9750-5827
Resource type: Preprint
Publisher: Zenodo
License: CC BY-SA 4.0 International
Related links:
- https://zenodo.org/records/17716954
- https://archive.org/details/quantum-entanglement-in-the-unified-framework-of-the-cosmology-of-the-quarkbase
- https://www.academia.edu/145246136/Quantum_Entanglement_in_the_Unified_Framework_of_the_Cosmology_of_the_Quarkbase