Entanglement: A myth introducing non-locality in any quantum theory

TL;DR

This paper challenges the concept of entanglement as non-locality, arguing it results from zero spin assumptions and proposing an experiment to test the true nature of remote particle correlations.

Contribution

It demonstrates that non-locality in quantum models arises from zero spin assumptions and suggests a way to test the actual spin states of remote particles.

Findings

Non-local energy transfer is unnatural in quantum models.

Non-locality stems from zero spin state assumptions.

Proposes an experiment to verify the spin state of remote particles.

Abstract

The purposes of the present article are: a) To show that non-locality leads to the transfer of certain amounts of energy and angular momentum at very long distances, in an absolutely strange and unnatural manner, in any model reproducing the quantum mechanical results. b) To prove that non-locality is the result only of the zero spin state assumption for distant particles, which explains its presence in any quantum mechanical model. c) To reintroduce locality, simply by denying the existence of the zero spin state in nature (the so-called highly correlated, or EPR singlet state) for particles non-interacting with any known field. d) To propose a realizable experiment to clarify if two remote (and thus non-interacting with a known field) particles, supposed to be correlated as in Bell-type experiments, are actually in zero spin state.