The H-type quark and the mass of mesons

Roza, Engel

doi:10.4006/0836-1398-25.2.191

Cited by 16 publications

(59 citation statements)

References 9 publications

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“…In line with the theory for mesons previously developed 9 and based on the considerations in Section III, we can consider the tauon to be an excited muon. This is illustrated by a graph of the potential energy at the center of mass in Fig.…”

Section: The Tauonmentioning

confidence: 95%

“…In previous articles, [7][8][9] we have described mesons, such as pions, as a structure of a particle and an antiparticle, which, under influence of an equilibrium between a repelling weak interaction force and an attractive strong interaction force, behaves as a quantum mechanical oscillator with a linear motion along the zaxis in a Cartesian frame described by cylindrical coordinates. The spacing between the two particles is determined by a dominant standing wave with a wavelength L determined by the de Broglie relationship L ¼ 2p"/(mv), with the particular property that v ' c because of the particle-antiparticle conjunction.…”

Section: Pion Decaymentioning

confidence: 99%

“…It is relevant, however, to establish the small mass difference between a charged meson and a neutral meson. 9 This correction factor p allows us to maintain the square root of the electromagnetic fine-structure constant as the quantum-mechanical coupling factor g, as expressed by the unification condition:…”

Section: Pion Decaymentioning

confidence: 99%

“…Within the scope of this article, a crude description of the decay process is given by the modeling of mesons and leptons as doublets, composed of quantum-mechanical oscillators, as proposed so far in a sequence of articles. [7][8][9] To some extent, this analysis will be based on the method described in Refs. 17 and 18. In this model, we have two kernels of energy at some spacing in between, bound together by a standing wave of bosonic energy.…”

Section: The Decay Of Muons and Tauonsmentioning

confidence: 99%

“…9 In this model, the origin of the nuclear force is ascribed to a Maxwellian potential field, analogous to the Coulomb field of an electron, with a particular format that has been derived from the functional description of the Higgs field. In this article, we wish to show that this model can be adequately used to calculate the masses of charged leptons.…”

Section: Introductionmentioning

confidence: 99%

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The H-type quark and the leptons

Roza¹

2012

Physics Essays

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Based on the assignment of a Higgs-type potential to quarks, an explanation is given for the origin of charged leptons. The mass relationships between charged leptons are calculated from the basic parameters of the Higgs field. The mass of the electron is calculated as well, without giving a spatial dimension to its shape. In addition, it is shown that the Htype, quark-based lepton model, as developed in the article, allows an analysis of the decay of leptons using the Fermi b-decay theory, thereby maintaining compatibility with the Feynman path-integral approach. Ó 2012 Physics Essays Publication.R´esum´e: Une explication, bas´ee sur l'attribution d'un potentiel de type Higgs aux quarks, est donn´ee pour l'origine des leptons charg´es. Les relations de masse entre les leptons charg´es sont calcul´ees`a partir des param`etres de base du champ de Higgs. La masse de l'´electron est egalement calcul´ee, sans qu'une dimension spatiale ne soit donn´ee`a sa forme. Il est en outre montr´e que le mod`ele de lepton bas´e sur le quark de type H, tel que d´evelopp´e dans cet article, permet une analyse de la d´esint´egration des leptons selon la th´eorie de la d´esint´egration b de Fermi, maintenant ainsi la compatibilit´e avec la technique de l'int´egrale de chemin de Feynman.

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Section: The Tauonmentioning

confidence: 95%

Section: Pion Decaymentioning

confidence: 99%

Section: Pion Decaymentioning

confidence: 99%

Section: The Decay Of Muons and Tauonsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The H-type quark and the leptons

Roza¹

2012

Physics Essays

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The gravitational constant as a quantum mechanical expression

Roza¹

2016

Results in Physics

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116

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A quantitatively verifiable expression for the Gravitational Constant is derived in terms of quantum mechanical quantities. This derivation appears to be possible by selecting a suitable physical process in which the transformation of the equation of motion into a quantum mechanical wave equation can be obtained by Einstein's geodesic approach. The selected process is the pi-meson, modeled as the one-body equivalent of a two-body quantum mechanical oscillator in which the vibrating mass is modeled as the result of the two energy fluxes from the quark and the antiquark. The quantum mechanical formula for the Gravitational Constant appears to show a quantitatively verifiable relationship with the Higgs boson as conceived in the Standard Model. keywords: gravitational constant; Higgs boson; quark model; pion; geodesic equation 1.IntroductionThe basic concept in quantum physics is the particle wave duality, which implies that a particle can dually be described by a mechanical equation of motion and by a quantum mechanical wave function. This wave function is the solution of a wave equation. The wave equation is obtained by a transformation of the particle's equation of motion in a way as conceived by Dirac [1]. Although Einstein's geodesic equation of motion [2] is the most generic of all, it is, so far, not adopted as the axiomatic base for the particle wave duality description. This is probably due to the mathematical complexity of 4D space-time. It is also the reason for the failure to unify quantum physics with gravity. Instead, Dirac derived his wave equation from the Einsteinean energy relationship of a particle in motion. Therefore, the equation is relativistic, but only special relativistic and not general relativistic. In this article I wish to develop the particle wave duality on the basis of Einstein's geodesic equation in 2D space-time and to compare it with Dirac's result. Next to that, I wish to motivate that the 2D space-time approximation is a justified modeling of a realistic physical process. This enables to relate gravity and quantum physics to the extent that the Gravitational Constant can be formulated as a quantitatively verifiable expression of quantum physical quantities. The concepts as will be outlined in this article, are invoked from previous work by the author [3]. Section 4 is devoted to a comparison of the 2D quantum mechanical wave equations as derived respectively by the geodesic approach (section 2) and Dirac's approach (section 3). This will result into an expression for the Gravitational Constant (section 5). In section 6 a physical process is selected that will deliver the quantity values. The result is subject to a relativistic correction (section 7). The final result is discussed in sections 8 and 9.The equations in this article will be formulated in scientific notation and the quantities will be expressed in SI units. Space-time will be described on the basis of the "Hawking" metric (+,+,+,+).

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The Spin-Spin Interaction Mechanism between Quarks and Its Impact on the Mass Spectrum of Mesons

Roza¹

2019

Preprint

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A structure-based view on mesons is given, based upon the concept of an archetype quark, described as a pointlike source producing an energy flux, the spatial description of which is derived from the functional description of the Higgs field. This enables to conceive the archetype meson (pion) as a structure that behaves as a one-body anharmonic quantum mechanical oscillator. All mesons appear being excitations of the archetype, thereby allowing a calculation of the mass spectrum without the use of empirical parameters for the masses of the quark flavors. This includes a physically comprehensible analysis of the spin-spin interaction between quarks. It also provides a solution for the eta-etaprime puzzle. Next to this, it is shown that quite some particles that are presently regarded as elementary, have a common root and can be traced back to a few archetypes only.

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The H-type quark and the mass of mesons

Cited by 16 publications

References 9 publications

The H-type quark and the leptons

The H-type quark and the leptons

The gravitational constant as a quantum mechanical expression

The Spin-Spin Interaction Mechanism between Quarks and Its Impact on the Mass Spectrum of Mesons

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