Investigation methods in model conception of quantum phenomena

TL;DR

This paper introduces the model conception of quantum phenomena (MCQP), a deterministic geometric approach that offers new insights into quantum behavior, including particle structure and pair production, surpassing traditional quantum mechanics methods.

Contribution

It proposes a new geometric framework for quantum phenomena, enabling deterministic modeling and revealing novel insights into particle structure and interactions.

Findings

MCQP relates to ACQP similarly as statistical physics relates to thermodynamics

The Dirac particle is a rotator of two particles around their center of inertia

A force field responsible for pair production is identified in MCQP

Abstract

One can construct the model conception of quantum phenomena (MCQP) which relates to the axiomatic conception of quantum phenomena (ACQP), (i.e. to the conventional quantum mechanics) in the same way, as the statistical physics relates to thermodynamics. Such a possibility is based on a new conception of geometry, which admits one to construct such a deterministic space-time geometry, where motion of free particles is primordially stochastic. The space-time geometry can be chosen in such a way that statistical description of random particle motion coincides with the quantum description. Methods of MCQP in investigation of quantum phenomena appear to be more subtle and effective than, that of ACQP. For instance, investigation of the free Dirac equation in framework of MCQP shows that the Dirac particle is in reality a rotator, i.e. two particles rotating around their common center of inertia. In the framework of MCQP one can discover the force field, responsible for pair production, that is impossible in the framework of ACQP.