Local origins of quantum correlations rooted in geometric algebra

TL;DR

This paper presents a geometric algebra-based framework that explains quantum correlations as local and realistic phenomena, challenging common interpretations of nonlocality in quantum mechanics.

Contribution

It refines a Clifford-algebraic geometric framework for local quantum correlations and addresses critiques, strengthening the theoretical foundation.

Findings

Supports local realistic explanations of quantum correlations

Strengthens the geometric algebra foundation of the framework

Refutes critiques against the geometric approach

Abstract

In previous publications I have proposed a geometrical framework underpinning the local, realistic, and deterministic origins of the strong quantum correlations observed in Nature, without resorting to superdeterminism, retrocausality, or other conspiracy loopholes usually employed to circumvent Bell's argument against such a possibility. The geometrical framework I have proposed is based on a Clifford-algebraic interplay between the quaternionic 3-sphere, or $S^3$, which I have taken to model the geometry of the three-dimensional physical space in which we are confined to perform all our physical experiments, and an octonion-like 7-sphere, or $S^7$, which arises as an algebraic representation space of this quaternionic 3-sphere. In this paper I first review the above geometrical framework, then strengthen its Clifford-algebraic foundations employing the language of geometric algebra, and finally refute some of its critiques.