A Chaotic, Deterministic Model for Quantum Mechanics

TL;DR

This paper proposes a deterministic, chaotic model for quantum mechanics based on metric tensor fluctuations, explaining quantum phenomena through high-frequency oscillations in space-time geometry.

Contribution

It introduces a novel model linking vacuum fluctuations, metric oscillations, and quantum properties within a classical 4D space-time framework.

Findings

Explains uncertainty relations via metric fluctuations

Models superposition, polarization, and entanglement with oscillating metrics

Proposes a crypto-stochastic interpretation of quantum phenomena

Abstract

With the decline of the Copenhagen interpretation of quantum mechanics and the recent experiments indicating that quantum mechanics does actually embody 'objective reality', one might ask if a 'mechanical', conceptual model for quantum mechanics could be found. We propose such a model. Vacuum energy fluctuations imply mass fluctuations and, through general relativity, curvature fluctuations. And those fluctuations are indicated by fluctuations of the metric tensor. The metric tensor fluctuations can 'explain' the uncertainty relations and non-commuting properties of conjugate variables. We argue that that the probability density is proportional to the square root of minus the determinant of the metric tensor (the differential volume element). We argue that the metric elements are not stochastic but are oscillating at a high enough frequency that measured values of same appear stochastic (i.e. crypto-stochastic). We suggest that the oscillations at the position of particles are described as torsional vibrations. A crypto-stochastic (or chaotic) oscillating metric yields, among other things, a model of super-position, photon polarization, and entanglement, and all within the confines of a 4-dimensional space-time.