Einstein's hated spooky action at a distance might just be a simple case of electrical signals locking their timing together.
Quantum entanglement is usually described as two particles communicating faster than light across the universe. This new model uses standard Maxwellian electrodynamics to show that these correlations can happen through local, deterministic phase-locking. By synchronizing rotating electric field vectors, the researchers reproduced the impossible results of Bell tests without needing non-locality. This suggests that the universe is not actually random or spooky at its core. It brings quantum weirdness back into the realm of classical, predictable physics.
A Deterministic Maxwellian Model for Bell-CHSH Violation via Synchronized Rotating Electric Field Vectors
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Abstract This paper proposes a local-deterministic completion of quantum entanglement by identifying the instantaneous phase of rotating electric field vectors as the primary hidden variable. We demonstrate that the observed violation of the Bell-CHSH inequality is not a signature of non-locality, but a natural consequence of the Intensity-Phase doubling mechanism inherent in Maxwellian electrodynamics. Through analytical derivation and discrete-time numerical integration, it proves that the cor