Completing the quantum ontology with the electromagnetic zero-point field

TL;DR

This paper argues that incorporating the electromagnetic zero-point field into quantum theory provides a more complete ontological framework, explaining quantum phenomena and nonlocality through a stochastic process distinct from classical Brownian motion.

Contribution

It introduces the zero-point field as an essential ontological component, offering a new perspective on quantum phenomena and their underlying mechanisms.

Findings

Explains atomic stationary states and transitions via the ZPF.

Provides an alternative interpretation of quantum nonlocality.

Highlights the qualitative change from classical to quantum descriptions.

Abstract

This text begins with a series of critical considerations on the initial interpretation of quantum phenomena observed in atomic systems. The bewildering explanations advanced during the construction of quantum mechanics are shown to have distanced the new theory from the rest of scientific knowledge, by introducing indeterminism, acausality, nonlocality, and even subjectivism as part of its interpretative framework. The conclusion drawn from this unsatisfactory interpretative landscape is that quantum mechanics lacks a key ontological ingredient. Arguments are given in favour of the random zero-point radiation field (ZPF) as the element needed to complete the quantum ontology. The (wave-mediated) quantum stochastic process is shown to be essentially different from Brownian motion, and more amenable to an analogy with the hydrodynamic case. The new perspective provided by the introduction of the ZPF is used to explain some salient features of quantum systems, such as the stationary atomic states and the transitions between them, and the apparent nonlocality expressed in the entangled states. Notably, the permanent presence of the field drastically affects the dynamics of the (otherwise classical) particle, which eventually falls under the control of the field. This qualitative change is reflected in the transition from the initial classical description in space-time, to the final quantum one in the Hilbert space. The clarification of the mechanism of quantization leads us to consider the possibility that a similar phenomenon occurs in other physical systems of corpuscles subjected to an oscillating background, of which the walking-droplet system is a paradigmatic example.