Algebrodynamics in complex space-time and the complex-quaternionic origin of Minkowski geometry

TL;DR

This paper develops a biquaternionic algebrodynamics framework based on nonlinear holomorphy conditions, proposing a geometric phase as a Lorentz-invariant that may explain quantum particle properties through complex space-time dynamics.

Contribution

It introduces a novel biquaternionic algebrodynamics model with a new Lorentz-invariant, the geometric phase, linking complex space-time structures to quantum particle behavior.

Findings

A new Lorentz-invariant geometric phase is identified.

Complex space-time dynamics are connected to quantum properties.

Field singularities correspond to particles in the model.

Abstract

We present a scheme of biquaternionic algebrodymamics based on a nonlinear generalization of the Cauchy-Riemann holomorphy conditions considered therein as fundamental field equations. The automorphism group SO(3,C) of the biquaternion algebra acts as a proper Lorentz group on a real space whose coordinates are bilinear in the complex coordinates of biquaternionic vector space. A new invariant of Lorentz transformations then arises - the geometric phase. This invariant can be responsible for the quantum properties of particles associated in this approach with field singularities. Some new notions are introduced, related to ``hidden'' complex dynamics: ``observable'' space-time, the ensemble of identical correlated particles-singularities (``duplicons'') and others.