Highlights
•
(The masses of) composite particles were computed via the rotating lepton model.
•
Some basic thermodynamic properties of these particles have been computed.
•
The gravitational Bohr type analysis uses SR and has no adjustable parameters.
The strong force can be modeled as relativistic gravity between neutrinos. (The weak force can be modeled as relativistic gravity between neutrinos and
(e)
(±)
Abstract
The rotating lepton model (RLM) of composite particles is used in conjunction with special relativity, the equivalence principle of inertial and gravitational mass, and the de Broglie wavelength equation, to compute analytically the masses, potential energies and Hamiltonians of 9 hadrons, 3 mesons and 3 bosons without any adjustable parameters. The model is also used to derive analytical formulae for their confining force and internal pressure and to compare with the experimental values measured recently via deeply virtual Compton scattering (DVCS) and computed via lattice Quantum Chromodynamics (LQCD) calculations. Agreement between the RLM computed masses and the experimental ones is, surprisingly, within 1% and supports the previously proposed notion that the strong force can be modeled as a relativistic gravitational force between neutrinos, and that the weak force can be modeled as a relativistic gravitational force between electrons or positrons with neutrinos or antineutrinos.
Keywords (Gravitational Bohr type models) (Rotating lepton model)
Hadronization modeling
Neutrino mass es
(©) Elsevier BV All rights reserved.
Read More
•
(The masses of) composite particles were computed via the rotating lepton model.
•
Some basic thermodynamic properties of these particles have been computed.
•
The gravitational Bohr type analysis uses SR and has no adjustable parameters.
The strong force can be modeled as relativistic gravity between neutrinos. (The weak force can be modeled as relativistic gravity between neutrinos and
(e)
(±)
Abstract
The rotating lepton model (RLM) of composite particles is used in conjunction with special relativity, the equivalence principle of inertial and gravitational mass, and the de Broglie wavelength equation, to compute analytically the masses, potential energies and Hamiltonians of 9 hadrons, 3 mesons and 3 bosons without any adjustable parameters. The model is also used to derive analytical formulae for their confining force and internal pressure and to compare with the experimental values measured recently via deeply virtual Compton scattering (DVCS) and computed via lattice Quantum Chromodynamics (LQCD) calculations. Agreement between the RLM computed masses and the experimental ones is, surprisingly, within 1% and supports the previously proposed notion that the strong force can be modeled as a relativistic gravitational force between neutrinos, and that the weak force can be modeled as a relativistic gravitational force between electrons or positrons with neutrinos or antineutrinos.
Keywords (Gravitational Bohr type models) (Rotating lepton model)
Hadronization modeling
Neutrino mass es
(©) Elsevier BV All rights reserved.
Read More
•
(The masses of) composite particles were computed via the rotating lepton model.
•
Some basic thermodynamic properties of these particles have been computed.
•
Abstract
The gravitational Bohr type analysis uses SR and has no adjustable parameters.
The strong force can be modeled as relativistic gravity between neutrinos. (The weak force can be modeled as relativistic gravity between neutrinos and
(e)
(±)
Abstract
The rotating lepton model (RLM) of composite particles is used in conjunction with special relativity, the equivalence principle of inertial and gravitational mass, and the de Broglie wavelength equation, to compute analytically the masses, potential energies and Hamiltonians of 9 hadrons, 3 mesons and 3 bosons without any adjustable parameters. The model is also used to derive analytical formulae for their confining force and internal pressure and to compare with the experimental values measured recently via deeply virtual Compton scattering (DVCS) and computed via lattice Quantum Chromodynamics (LQCD) calculations. Agreement between the RLM computed masses and the experimental ones is, surprisingly, within 1% and supports the previously proposed notion that the strong force can be modeled as a relativistic gravitational force between neutrinos, and that the weak force can be modeled as a relativistic gravitational force between electrons or positrons with neutrinos or antineutrinos.
Keywords (Gravitational Bohr type models) (Rotating lepton model)
Hadronization modeling
Neutrino mass es
(©) Elsevier BV All rights reserved.
Read More
Keywords (Gravitational Bohr type models) (Rotating lepton model)
Hadronization modeling
(Gravitational Bohr type models) (Rotating lepton model)
Hadronization modeling
Neutrino mass es
(©) Elsevier BV All rights reserved.
Read More
Neutrino mass es
(©) Elsevier BV All rights reserved.
Read More
Read More
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