High Energy Particle Physics

Mass Spectrum of the Charmed-Strange Mesons

Authors: D. G. Grossman
Comments: 18 Pages.

This paper is about the mesons PDG calls charmed-strange (cs mesons). However, according to the results of n-sphere surface volume factoring, it appears that only two or three of those mesons are actually cs mesons. Most of the rest of them are either cc, cb, or bt mesons. One of them, the Ds(2713), is a tetraquark. Obviously, the rules currently used to determine quark content do not give correct results in all cases, but you can decide for yourself if the conclusions about the quark content of these mesons are correct by analyzing the reasoning behind their quark content determinations, which isexplained in the paper.
Category: High Energy Particle Physics

Cold Fusion (CF) Chain Reaction and Non-mechanical Engine

Authors: A. P. Nikitin
Comments: 4 Pages.

Движение материи, [в том числе Cold Fusion (CF) и гравитационное (G)], описание которого и есть задача науки, можно познать постулируя первичность движения нашего Мира - Cosmos как способа его существования, что подтверждается всем нашим опытом.

Matter motion [including Cold Fusion (CF) and gravitational (G)], the description of which is the task of science, can be cognized by postulating the primacy of the movement of our World - Cosmos as a way of its existence, which is confirmed by all our experience.
Category: High Energy Particle Physics

W Boson?

Authors: Michael Tzoumpas
Comments: 14 Pages.

The beta decay is the second grand Cosmic event of the Universe and is interpreted by the increased cohesive pressure, by the electric entity of the macroscopically neutral neutron and by the inductive-inertial phenomenon. It is a new interpretation of E/M and weak nuclear forces. Their integration with the strong nuclear and gravitational force is achieved with the unified field of the dynamic space, which is identical with the Higgs field, while the homonymous boson is located in the core of the particles and in black holes as space holes after the collapse of the stellar matter. The unconfirmed results (found from the team of the Fermilab Accelerator), that the W boson is more massive, suggest deviations from the Standard Model and come possibly as a result of an as yet undiscovered fifth force of Nature, are no longer needed to be interpreted or justified.
Category: High Energy Particle Physics

The Structure of The Proton and the Calculation of Its G-factor (Some Recent Results from Ether Electrodynamics)

Authors: Joseph Catania Jr.
Comments: 14 Pages. (c) 2022 by Joseph Catania, not to be redistributed or reproduced without permission.

Some recent results of a more rigorous electrodynamics than Special Relativity or Quantum Electrodynamics are summarized with some pedagogy. The results include the correct explanation of line radiation, the correct interpretation of the g-factor, the introduction of the precessional mass, the dismissal of the half-quantum, the deduction of the proton structure from first principles, and a ”T-shirt” calculation of the proton g-factor.
Category: High Energy Particle Physics

A Newtonian Alternative to Special Relativity

Authors: Eric A. Samuel
Comments: 32 Pages.

This paper offers elegant Newtonian explanations for key experiments that support special relativity (SR). Rossi’s high altitude µ-meson measurements are shown to accurately reveal µ-meson flight times between known altitudes, consistent with µ-meson speeds of up to 20 c, thus contradicting SR’s universal speed limit concept. The speed-limited E field and spiral H-field trajectories of electrons are explained classically by augmenting the Lorentz force with a flux-proportional radiation damping Lentz force: F = (eE + e v x B ) - [(e/c) (v ∙E) E/|E| + e α (B x v x B)/|B|] In the above model, an electron in an E-field reaches a terminal velocity of c when its Lorentz motive and radiation damping forces are equally opposed. The spiral trajectories of charged particles in H-fields are shown to be due to the progressive radiation dampening of their tangential velocities while their Lawrence cyclotron frequencies remain unaffected. The remarkable experiments of Ives and Stillwell, and of Kundig are re-interpreted as being due to impulsive momentum transfer to photons emitted from accelerating molecules or nuclei. However, the impulsive momentum transfer time is a fraction of the photon emitter lifetime that is proportional to the characteristic light transit time. SR’s time-dilatation formulation is shown to be theoretically flawed because: (i) both its postulates are traceable to Newton’s Corollary V, in which time and mass invariance are implicit, and (ii) SR’s unjustified expectation of an inertial frame outcome for a non-inertial experimental design that places observer and apparatus in separate frames; a simple solution by Galilean velocity transformation proves no time dilation. Additionally, SR’s time dilation formulation is ambiguous for rotations and wave-clock types. Replacing the light clock with a sonar clock also leads to ambiguous time dilations and an unlikely upper speed limit. Consequently, Newton’s laws alone are sufficient to fully explain the experimental data that are now believed to support SR.
Category: High Energy Particle Physics

Mass Calculation of Antiproton

Authors: Deokjin Kim
Comments: 2 Pages.

In previous study, the masses of proton, kaon, and pion were calculated. Proton of 938.3 MeV is composed of two up quarks, one down quark, one strong particle force and the dark force, and one electromagnetic particle force and the dark force. The shell of antiproton is one anti-electromagnetic particle force, which is 2π times heavier than electromagnetic particle force. From this, the mass of antiproton was calculated as 5.895 GeV. The minimum kinetic energy required to produce an antiproton is 5.6 GeV, and the first experiment to confirm the existence of antiproton was the collision of copper target and protons accelerated to 6.2 GeV. The average mass of two values is 5.9 GeV, and the calculated value of antiproton is 5.895 GeV. Is this coincidence or necessity?
Category: High Energy Particle Physics

The Origin of the High-Mass Paired Dijet Resonances

Authors: Sylwester Kornowski
Comments: 3 Pages.

Within the Scale-Symmetric Theory (SST) we obtain the three invariant masses on the tail of the distributions: the four-jet masses of 8.03 TeV and 7.79 TeV and a dijet mass of 1.95 TeV.
Category: High Energy Particle Physics