Preprint Article Version 1 This version is not peer-reviewed

Emergence of Standard-Model-Like Fields and Particles in Gravitation-Diffusion Vacuum

Version 1 : Received: 8 October 2018 / Approved: 8 October 2018 / Online: 8 October 2018 (14:29:00 CEST)

How to cite: Manasson, V.A. Emergence of Standard-Model-Like Fields and Particles in Gravitation-Diffusion Vacuum. Preprints 2018, 2018100150 (doi: 10.20944/preprints201810.0150.v1). Manasson, V.A. Emergence of Standard-Model-Like Fields and Particles in Gravitation-Diffusion Vacuum. Preprints 2018, 2018100150 (doi: 10.20944/preprints201810.0150.v1).

Abstract

A number of experiments suggest that the elementary particles are non-local entities. A dissipative self-organization, that treats particles as open systems may provide a better understanding of the underlying phenomena than conservative models. The proposed toy model is such an attempt. We found that self-gravitation (although accompanied by self-diffusion) may not only be compatible with the quantum phenomena but is perhaps the major reason for the existence of quantum fields. According to the proposed model, fields/particles (resemble those of the Standard Model) emerge from a dynamic self-organized medium (which we associate with vacuum dust) from competition between self-gravitation and self-diffusion. These forces produce turbulence in the form of vortices (which we call vacuum cells) that serve as the building blocks for fields and particles. Field/particle features and symmetries are based on their internal (intracellular) dynamics and vortex synchronization (intercellular dynamics). This model allows for rough estimations of relative field coupling strengths, the quantity of charges and flavors, the probabilities of quark transmutations, the dimensionality and the topologies of phase spaces, and other Standard Model parameters that came not from the theory but rather determined by experiment.

Subject Areas

particle physics; unification of forces; self-organization; coupling constants; quark flavors; quark mixing amplitudes; quantum statistics; open systems; Feigenbaum universality; synchronization

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