The Annals of Exploratory Science

Two- and Three-Scale Polyphase (Local (Sub--Atomic) - Nonlocal) Galilean Electric and Magnetic Fields in a Solid and Nano-powdered Cu and Ni (Copper and Nickel)

Vladi S. Travkin,$^{1,\ast }$

$^{1}$ Hierarchical Scaled Physics and Technologies (HSPT), Rheinbach, Germany, Denver, CO, USA

ABSTRACT

We are using advances in the 3P (Polyphase-Polyscale-Polyphysics) particle physics and sub-atomic scales electrodynamics theory and advance the modeling capabilities for the CF (cold fusion) processes depiction in direction that gives the tools to model and simulate the polyscale electromagnetic phenomena in a solid phase and nano-powdered metals Cu and Ni. The reason and interest are stemming from the significant roles that play both metals in CF Rossi type demonstrated reactors.

The problem with electrodynamics specifically is that seems nobody, especially of COHP (Conventional Orthodox Homogeneous Physics) specialists is even talking qualified on the electromagnetic phenomena in Rossi CF (RCF) reactors. Rossi himself probably doesn't know what is the specific actions of EM in the activation of working dynamics in a reactor. The examples of COHP electrodynamics in the reactor are not satisfactory for accepting as an explanation of the electrodynamics within the RCF. The purpose of understanding of EM phenomena in RCF reactor is that there is the polyphase polyscale electrodynamics within the RCF reactor, with the critical role in activation and for the transmutation and stability of the processes, nevertheless, COH physics is not familiar with the correct polyscale science due to a few reasons, known and published reasons. Also, the Maxwell-Heaviside-Lorentz (MHL) electrodynamics is not suited and has noted with the insufficiencies for application to the polyscale polyphase media.

We demonstrate the features of polyscale polyphase electrodynamics of MHL and Galilean electrodynamics' applied to polyscale - from the sub-atomic to meso-scale continuum mechanics environments in RCF reactor. This kind of theory we believe gives the ability to model and simulate the basic polyscale control electromagnetic phenomena within the RCF reactor. Meanwhile, that is the fundament for the reactor's function, the nuclei collapse and transmutation. Not the activities around of explanation for the temperature, pressure, boiling or not boiling, and phase mobilities in reactor.

We use the structured models of Ni, Cu and H nuclei in the vessel of reactor. Structured models of nuclei and electrons, other known particles all have the EM fields of the lower (sub-atomic) scales, while their collective interaction controlled by the introduced EM pulsating fields is the reason and source of collapsing and transmuting of metal elements.

The following article will describe and explain in more or less simple text the scaled subjects regarding the Two- and Three-Scale Polyphase (Local (Sub--Atomic) - Nonlocal) Galilean Electric and Magnetic Fields in a Solid and Nano-powdered Cu and Ni (Copper and Nickel):

  • Two- and Three-Scale Polyphase (Local (Sub--Atomic) - Nonlocal) Galilean Electric and Magnetic Fields in a Solid and Nano-powdered Cu and Ni (Copper and Nickel) **

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    This is also the well known problem - still can not be solved within the Homogeneous One-Scale particle physics, electromagnetism, nuclear physics.

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