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| viXra.org > Quantum Physics > 2110 |
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[7] viXra:2110.0176 [pdf] submitted on 2021-10-30 12:21:58
Authors: Miroslav Pardy
Comments: 9 Pages. original article
The equivalent system of equations corresponding to the Dirac equation is derived and
the WKB approximation of this system is found. Similarly, the WKB approximation for the
equivalent system of equation corresponding to the squared Dirac equation is found and it
is proved that the Lorentz equation and the Bargmann-Michel-Telegdi iquations follow from
the new Dirac-Pardy system. The new tensor equation with sigma matrix is derived for the
verification by adequate laboratories.
Category: Quantum Physics
[6] viXra:2110.0173 [pdf] submitted on 2021-10-29 17:34:23
Authors: Victor Vaguine
Comments: 15 Pages.
Properties of the intrinsic electron are described including the inner structure, definition of the c-ring, description of electromagnetic field configuration, determination of self-mass, spin and magnetic moment, issue of stability, and definition of the position parameter.
Category: Quantum Physics
[5] viXra:2110.0164 [pdf] replaced on 2025-06-11 20:13:42
Authors: Henok Tadesse
Comments: 14 Pages.
The microscopic mechanism underlying transmission of light in transparent media is still unknown. The Ewald-Oseen extinction theorem is an attempt to explain it mathematically but not very convincing. In this paper, we present a new explanation to the phenomena of light transmission in transparent media, light reflection and refraction. The mystery of ‘where the energy goes’ during destructive interference of light will be revealed.
Category: Quantum Physics
[4] viXra:2110.0144 [pdf] submitted on 2021-10-24 11:54:25
Authors: V.A. Kuz`menko
Comments: 3 Pages.
The relevance of such a replacement has long been ripe and overripe.
Category: Quantum Physics
[3] viXra:2110.0083 [pdf] submitted on 2021-10-16 03:12:46
Authors: Didier F Viel
Comments: 9 Pages.
Newton's Law of Universal Gravitation provides the basis for calculating the attraction force between two bodies, which is called the "gravitational force" \cite{Newton gravitation}. This Law uses the "mass" of bodies.
Einstein General Relativity Theory proposes to calculate this gravitational force by using the curvature of space-time. This space-time curvature is supposedly due to the same "mass" \cite{Einstein}.
Stephan Hawkings in his book (A Brief History of Time)\cite{Hawkings} supposes that gravitons particles of quantum mechanics are the intermediaries that "give mass" to the bodies. However, there is no explanation about the nature of the gravitons or how their interaction with bodies could "give them mass".
This paper presents a new way of explaining how the "mass" can be given to bodies.
The starting point is an idea proposed in 1690 by Nicolas Fatio de Duillier and revisited here with new hypotheses, and then further developped with the use of the Bohmian quantum mechanics. It is shown, by means of reasoning and equations reflecting these reasoning, that the gravitational force between two bodies comes from the interaction between the revisited Nicolas Fatio's aether and matter atomic nuclei.
It is also shown that the "mass" of a body is not a real entity, but is an emerging phenomenon. This idea has already been suggested by Erick Verlinde in another context \cite{Verlinde}. Here, the emergence of "mass" is given by the interaction of the aether particles with matter atomic nuclei.
The interesting point of Nicolas Fatio’s theory is that it is able to solve not only the origin of gravitational force, but also the origin of inertial force. The origin of inertia comes from an induction phenomena between Nicolas Fatio's aether and matter atomic nuclei.
This paper uses Nicolas Fatio's medium own word, aether, to describe gravitation and inertia. It has nothing to do with Lorentz or Maxwell luminiferous aether that has been disproved by the scientific community after the Michelson and Morley experiment.
Category: Quantum Physics
[2] viXra:2110.0057 [pdf] replaced on 2021-12-21 16:44:37
Authors: Dirk J. Pons
Comments: 30 Pages. Preprint version. Published as Pons, D.J., Motion of particles at the fundamental level: NLHV theory predictions for a spiral gait locus. Journal of Modern Physics, 2021(12): p. 1931-1953, DOI: http://dx.doi.org/10.4236/jmp.2021.1214110
Context - The existing literature on particle motion at the fundamental level is sparse. Particles, whether classical or quantum, are assumed to move with a continuous (even if uncertain) velocity. Purpose - The work prospects for a descriptive theory of particle motion from a non-local hidden-variable (NLHV) perspective. This is worth attempting for the potential to better understand fundamental dynamics and kinematics. Method - The new physics provided by the cordus theory was used to infer the mathematical representation of the energisation behaviour of the inner structures, specifically the reactive ends. From this the motion function of the particle as a whole was determined. Findings - In three dimensional space the motion of each reactive end is an irregular spiral displacement locus. The motion comprises a movement phase and a brief immobile phase. This is called a ‘gait’ as it is reminiscent of biological locomotion. Originality - A novel theory of particle motion is offered. The theory predicts that motion comprises a complex spiral locus of the particle. This is unique among theories of physics. Further contributions are the provision of explanations for several physical phenomena: ponderomotive force, the nature of momentum, and bremsstrahlung radiation. Specifically, the theory explains why photon emission would be increasing concentrated in the forward direction with increased electron energy. The theory provides a means to bridge quantum mechanics and special relativity, because it accommodates both particle uncertainty and field transmissions.
Category: Quantum Physics
[1] viXra:2110.0031 [pdf] submitted on 2021-10-07 11:27:37
Authors: Gerard van der Ham
Comments: 22 Pages.
yet have definite shapes at any moment? Could it be that quanta have statistical definite properties, wave- and particle properties at the same time? These questions need an answer to reach some consensus in physics and to solve some of the most urgent problems in physics. These questions will be answered in this paper.
Also the probabilities in Bell experiments, predicted by quantum mechanics, are made visible and their explanation is accounted for mathematically.
Category: Quantum Physics
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