Vacuum Texture: A New Interpretation of Quantum Mechanics and a New Loophole for Bell's Inequality Measurements that preserves Local Realism and Causality

TL;DR

This paper proposes a novel interpretation of quantum mechanics based on an inhomogeneous vacuum texture, which preserves local realism and causality, and introduces a new loophole in Bell's inequality experiments.

Contribution

It introduces the vacuum texture interpretation, providing a new loophole in Bell's experiments that aligns with local realism and causality, challenging conventional quantum entanglement views.

Findings

Selected Bell's experiments are consistent with the vacuum texture interpretation.

The interpretation suggests particles are influenced by vacuum texture, not entanglement.

A proposed experiment aims to confirm the vacuum texture hypothesis.

Abstract

We introduce a new interpretation of quantum mechanics by examining the Einstein, Podolsky and Rosen's (EPR) paradox and Bell's inequality experiments under the assumption that the vacuum has an inhomogeneous texture for energy levels below the Heisenberg time-energy uncertainty relation. In this article, selected results from the most reliable Bell's inequality experiments will be quantitatively analyzed to show that our interpretation of quantum mechanics creates a new loophole in Bell's inequality, and that the past experimental findings do not contradict our new interpretation. Under the vacuum texture interpretation of quantum mechanics in a Bell's inequality experiment, the states of the pair of particles created at the source (e.g. during parametric down conversion) is influenced by an inhomogeneous vacuum texture sent from the measurement apparatus. We will also show that the resulting pair of particles are not entangled and that the theory of vacuum texture preserves local realism with complete causality. This article will also suggest an experiment to definitively confirm the existence of vacuum texture.