Algbrodynamics over complex space and phase extension of the Minkowski geometry

TL;DR

This paper develops a novel algebrodynamics framework based on biquaternion algebra, deriving physical geometry and dynamics from algebraic properties, and introduces complex space structures that offer an alternative explanation for quantum interference.

Contribution

It presents a new approach to physics where geometry and dynamics emerge from biquaternion algebra, including complex space structures and a phase invariant, providing an alternative to wave-particle duality.

Findings

Effective real geometry is Minkowski-like with a phase invariant.

Primordial dynamics involve correlated matter pre-elements called duplicons.

Introduces a complex time concept leading to macrolevel irreversibility.

Abstract

First principles should predetermine physical geometry and dynamics both together. In the "algebrodynamics" they follow solely from the properties of the biquaternion algebra $\B$ and the analysis over $\B$. We briefly present the algebrodynamics on the Minkowski background based on a nonlinear generalization to $\B$ of the Cauchi-Riemann analyticity conditions. Further, we consider the effective real geometry uniquely resulting from the structure of multiplication in $\B$ which turns out to be of the Minkowski type, with an additional phase invariant. Then we pass to study the primordial dynamics that takes place in the complex $\B$ space and brings into consideration a number of remarkable structures: an ensemble of identical correlated matter pre-elements ("duplicons"), caustic-like signals (interaction carriers), a concept of random complex time resulting in irreversibility of physical time at a macrolevel, etc. In partucular, the concept of "dimerous electron" naturally arises in the framework of complex algebrodynamics and, together with the above-mentioned phase invariant, allows for a novel approach to explanation of quantum interference phenomena alternative to the recently accepted paradigm of wave-particle dualism.