Abstract
When the electrically charged elementary particles of “normal” matter like protons and electrons mutually interact, their masses interact gravitationally and charge electrically. There is no interaction between the mass of one and charge of other particle. In this paper, we describe a prediction of the existence of a “pseudo-charge” of the same size as the common elementary electric charge, which seems to be possessed by neutrinos. If the prediction is relevant to the reality, the pseudo-charge interacts with the mass of normal particle in the interaction between this particle and neutrino. Consequently, the cross-section in a collision between neutrino and particle of normal matter is many orders of magnitude lower than that in the mutual collisions of normal-matter particles. However, the pseudo-charge of one neutrino interacts with the pseudo-charge of other neutrino in a mutual interaction of neutrinos and, consequently, their collisional cross-section is predicted to be again relatively large, essentially the same as that in, e.g., electron-electron collisions. We propose an experimental verification of the possible existence of neutrinic pseudo-charge with the help of two mutually crossing neutrino beams.
Highlights
Albert Einstein devoted many years of his scientific activities to a search for an unified description of four well-known interactions in the universe
It appeared that the classical theory of electro-magnetism by Maxwell [3], completed with two formulas given into the quantum physics by de Broglie [4] [5] and with the concept of evanescent wave known from the classical physics, can describe the atom within the theory alone, without any addition of the principles of quantum physics
Our analysis of the potential kinds of interaction, based essentially on the Maxwellian electromagnetism, predicts an existence of elementary particles possessing a pseudo-charge with the size equal to that of common elementary electric charge, which does not interact with the charge of normal particles, but with the mass of the latter
Summary
Albert Einstein devoted many years of his scientific activities to a search for an unified description of four well-known interactions in the universe. The orientation of gravity with respect to the orientation of electric force between two charged particles was, basically, derived from the equation. Because we need only three matrices of the set of four to decompose Equation (1) and, there are a lot of combinations of the sequential order of these matrices, there is a plenty of possibilities for the decomposition, whereby each of these possibilities implies a specific kind of interaction between two considered particles. Because these properties appear to be, at least qualitatively, identical to those, which are known for neutrinos, we identify the M-IPs to these tiny, weird particles and derive a consequence relevant to the dark matter in the universe. We suppose that the experiment could be performed already at the present, using the technical facilities of the most advanced physical laboratories (particle accelerators) in the world
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