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A Natural Mass Unit Hidden in the Planck Action Quantum

Binder, Bernd (2003) A Natural Mass Unit Hidden in the Planck Action Quantum. [Preprint]

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Abstract

0.138% above the neutron and 0.276% above the proton baryon mass a natural mass unit µ can be identified by extrapolating dimensionless Planck units h=c=1 to the System of Units (SI). Similar to quantum measurements that determine h it is only necessary to relate the unit kinetic particle energy to the quantum energy of a photon having a unit wavelength. Connecting both energies and shifting the units, the inverse ratio of length units evolves proportional to the square of velocity units since both are proportional to the energy unit. With this connection the measurement of h becomes an indirect light velocity measurement and measurement of µ and shows that nonzero action and mass quanta corresponds to a finite light velocity c. As already shown, these sequential baryon mass differences (typical mass deficits of strong interaction) including the electron mass can be recovered within measurement error (some ppm) by simple relations obtained from bosonizing a massive Dirac equation.


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Item Type: Preprint
Creators:
CreatorsEmailORCID
Binder, Bernd
Keywords: baryon, quantum, Compton, Dirac, topological, fundamental, particle, spin, proton, electron, neutron, bosonization, modes, nonlinear, soliton, breather, nonpertubative, phase, berry, sine-Gordon, fine structure, iteration, iterative, exact
Subjects: Specific Sciences > Physics > Fields and Particles
General Issues > Laws of Nature
Specific Sciences > Physics
Specific Sciences > Physics > Quantum Field Theory
Specific Sciences > Physics > Quantum Mechanics
Specific Sciences > Physics > Relativity Theory
Depositing User: Dr. Bernd Binder
Date Deposited: 08 Jan 2003
Last Modified: 07 Oct 2010 15:11
Item ID: 962
Subjects: Specific Sciences > Physics > Fields and Particles
General Issues > Laws of Nature
Specific Sciences > Physics
Specific Sciences > Physics > Quantum Field Theory
Specific Sciences > Physics > Quantum Mechanics
Specific Sciences > Physics > Relativity Theory
Date: January 2003
URI: https://philsci-archive.pitt.edu/id/eprint/962

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