Strong Interactions in Crystalline Vacuum

TL;DR

This paper proposes a multiscale expansion approach to describe a crystalline vacuum state formed by resonant interactions of Planck-scale waves, offering new insights into quantum uncertainty, dark matter, and energy.

Contribution

It introduces a novel multiscale expansion method to model the vacuum as a crystal influenced by Planck-scale wave interactions, linking particle properties to vacuum lattice asymmetries.

Findings

Quarks modeled as elastic modulations of the vacuum crystal

Vacuum lattice asymmetries explain flavor distinctions

Theory provides new perspectives on quantum uncertainty and dark matter

Abstract

A multiscale expansion procedure reveals a crystalline vacuum state arising as a result of resonant interactions among weak Planck-scale waves on spinor and cospinor manifolds. Quarks are presented as elastic modulations of the vacuum crystal. The complementing modes are identified with colors, and distinctions between flavors are attributed to asymmetries of the vacuum lattice. Repercussion of the theory include insights into the nature of quantum uncertainty and dark matter and energy.