High Energy Particle Physics

1811 Submissions

[13] viXra:1811.0186 [pdf] submitted on 2018-11-13 02:30:14

The Volkov Solution of the Dirac Equation with the Higgs Field

Authors: Miroslav Pardy
Comments: 8 Pages. The original ideas

We determine the power radiation formula of the electron moving in the plane wave Higgs potential from the Volkov solution of the Dirac equation. The Higgs potential is here the vector extension of the scalar Higgs potential. The Higgs bosons mass is involved in the power radiation formula. The article represents the unification of the particle and the laser physics.
Category: High Energy Particle Physics

[12] viXra:1811.0185 [pdf] submitted on 2018-11-13 02:49:53

What is a Neutrino?

Authors: Michael Tzoumpas
Comments: 4 Pages.

The emission of antineutrinos is interpreted by the inductive-inertial phenomenon as independent E/M formations, which are created when a neutron breaks down into a proton and an electron (beta decay). Specifically, at the contact limits of the neutron quarks, due to the acceleration of the surface charges of the neutron cortex, the adjacent opposite units are strongly accelerated, causing grouping units outside the neutron cortex as independent E/M formations of one spindle.
Category: High Energy Particle Physics

[11] viXra:1811.0155 [pdf] submitted on 2018-11-09 07:53:59

Spacetime at Quarks Scale

Authors: George Rajna
Comments: 51 Pages.

Most physicists believe that the structure of spacetime is formed in an unknown way at the Planck scale, i.e., at a scale close to one trillionth of a trillionth of a metre. [30] In a recent study, the CMS collaboration describes how it has sifted through data from the Large Hadron Collider (LHC) to try and spot dark quarks. [29] Physicists in Italy are about to start up a new experiment designed to hunt for hypothetical particles such as the “dark photon” and carriers of a possible fifth force of nature. [28] A signal caused by the very first stars to form in the universe has been picked up by a tiny but highly specialised radio telescope in the remote Western Australian desert. [27] This week, scientists from around the world who gathered at the University of California, Los Angeles, at the Dark Matter 2018 Symposium learned of new results in the search for evidence of the elusive material in Weakly Interacting Massive Particles (WIMPs) by the DarkSide-50 detector. [26]
Category: High Energy Particle Physics

[10] viXra:1811.0139 [pdf] submitted on 2018-11-08 08:40:31

Four Top Quarks At Once

Authors: George Rajna
Comments: 69 Pages.

A promising testbed for such new physics is "four-top-quark production," an elusive Standard Model process that has not yet been observed experimentally. [40] Compared with the previous method of data pre-processing, the new machine-learning-based method has quadrupled quality metrics for the identification of particles on the calorimeter. [39] From the data collected by the LHCb detector at the Large Hadron Collider, it appears that the particles known as charm mesons and their antimatter counterparts are not produced in perfectly equal proportions. [38] The OPERA experiment, located at the Gran Sasso Laboratory of the Italian National Institute for Nuclear Physics (INFN), was designed to conclusively prove that muon-neutrinos can convert to tau-neutrinos, through a process called neutrino oscillation, whose discovery was awarded the 2015 Nobel Physics Prize. [37] The Precision Reactor Oscillation and Spectrum Experiment (PROSPECT) has completed the installation of a novel antineutrino detector that will probe the possible existence of a new form of matter. [36] The MINERvA collaboration analyzed data from the interactions of an antineutrino—the antimatter partner of a neutrino—with a nucleus. [35]
Category: High Energy Particle Physics

[9] viXra:1811.0137 [pdf] submitted on 2018-11-08 10:24:14

New Concept of Elementary Particles Classification

Authors: Ilgaitis Prūsis, Peteris Prūsis
Comments: 6 pages, 2 figures

In contemporary physics elementary particles are classified by energy, live time and other properties. In contradiction to this very basic principle of contemporary physics, this article proposes a new concept that particles in the gravitation field like in the electric field have allowed energy levels. Only four elementary particles, i.e., electron, proton, photon and neutrino are in the ground state. They are intrinsically elementary particles. All other particles are excited states of said intrinsic particles in the gravitation field of Earth.
Category: High Energy Particle Physics

[8] viXra:1811.0134 [pdf] submitted on 2018-11-08 20:22:54

Action and Holographic Principle

Authors: Kuyukov Vitaly
Comments: 2 Pages.

Applying the holographic principle to action
Category: High Energy Particle Physics

[7] viXra:1811.0114 [pdf] submitted on 2018-11-07 14:43:27

Theory of Fermion Masses, Mixing Angles, Lagrangian Potentials and Beta Decays, Based on Higgs Bosons Arising from the Scaler Fields of a Kaluza Klein Theory Given Five-Dimensional General Covariance by Dirac’s Quantum Theory of the Electron

Authors: Jay R. Yablon
Comments: 162 Pages.

Why the twelve elementary fermions have the masses they have, (and what the neutrino masses actually are) is one of the deepest unsolved mysteries of modern physics. We crack this puzzle using a theory of fermion masses which succeeds in reparameterizing all twelve fermion masses in terms of other known parameters for which the theoretical interconnection to these masses have not heretofore been understood. The first step is to “repair” long-recognized perplexities of Kaluza-Klein theory using Dirac’s quantum theory of the electron to enforce general covariance across all five dimensions. One consequence of this is the emergence of a modified Dirac equation for fermions which naturally contains the Kaluza-Klein scaler. After establishing a connection between this Kaluza-Klein scaler and the standard model Higgs scaler, we use the latter to connect the known masses of all the quarks and charged leptons to the CKM and PMNS mixing angles and several other parameters which have heretofore not been theoretically connected to these masses. Then, after using the Newton gravitational constant and the Fermi vacuum to establish a sum of neutrino masses in the exact range expected from experiments, it also becomes possible to predict the rest masses of the three neutrinos. Also predicted are the existence and rest mass of a second leptonic Higgs boson, and tighter values for several other known parameters including the mass of the established Higgs boson. Also uncovered is a new, deep role for the cosmological neutrino background (CvB) and the Higgs boson in triggering and facilitating weak interaction beta decay events.
Category: High Energy Particle Physics

[6] viXra:1811.0065 [pdf] submitted on 2018-11-04 06:41:07

Correction to the Yinyang Logic Schema

Authors: Colin James III
Comments: 1 Page. © Copyright 2018 by Colin James III All rights reserved. Respond to the author by email at: info@ersatz-systems dot com.

The operator described as an addition rule ⨣ is mistaken as such because it is not bivalent and exact, but rather a vector space and probabilistic. The operator ⨣ is re-named as "the operator rules of classical logic" because of the following schema: 01 Or 01 = 01; 10 Or 10 = 10; 01 And 10 = 00; 00 Or 11 = 11.
Category: High Energy Particle Physics

[5] viXra:1811.0034 [pdf] submitted on 2018-11-02 12:43:56

Antimatter Gravity at CERN

Authors: George Rajna
Comments: 32 Pages.

Two new experiments at CERN, ALPHA-g and GBAR, have now started their journey towards answering this question. [25] Mysterious radiation emitted from distant corners of the galaxy could finally be explained with efforts to recreate a unique state of matter that blinked into existence in the first moments after the Big Bang. [24] Researchers at Oregon State University have confirmed that last fall's union of two neutron stars did in fact cause a short gamma-ray burst. [23] Quark matter – an extremely dense phase of matter made up of subatomic particles called quarks – may exist at the heart of neutron stars. [22] When a massive astrophysical object, such as a boson star or black hole, rotates, it can cause the surrounding spacetime to rotate along with it due to the effect of frame dragging. [21] Rotating black holes and computers that use quantum-mechanical phenomena to process information are topics that have fascinated science lovers for decades, but even the most innovative thinkers rarely put them together. [20] If someone were to venture into one of these relatively benign black holes, they could survive, but their past would be obliterated and they could have an infinite number of possible futures. [19] The group explains their theory in a paper published in the journal Physical Review Letters—it involves the idea of primordial black holes (PBHs) infesting the centers of neutron stars and eating them from the inside out. [18] But for rotating black holes, there's a region outside the event horizon where strange and extraordinary things can happen, and these extraordinary possibilities are the focus of a new paper in the American Physical Society journal Physical Review Letters. [17] Astronomers have constructed the first map of the universe based on the positions of supermassive black holes, which reveals the large-scale structure of the universe. [16] Astronomers want to record an image of the heart of our galaxy for the first time: a global collaboration of radio dishes is to take a detailed look at the black hole which is assumed to be located there. [15]
Category: High Energy Particle Physics

[4] viXra:1811.0033 [pdf] submitted on 2018-11-02 14:16:28

The Bumps in the Di-Muon Mass Spectra at 28.3 GeV in the LHC Data and 30.4 GeV in the LEP Data

Authors: Sylwester Kornowski
Comments: 2 Pages.

The atom-like structure of baryons described within the Scale-Symmetric Theory (SST) shows that for colliding nucleons we should observe an excess in the di-muon mass spectra at 28.3 GeV with a natural width 1.5 GeV while for colliding electrons should be respectively 30.2 GeV and 1.6 GeV. Obtained here results are consistent with the initial results obtained in the CMS and ALEPH experiments.
Category: High Energy Particle Physics

[3] viXra:1811.0025 [pdf] submitted on 2018-11-03 06:05:38

Estimation and Prediction of Neutrino Mass Based on the Kinetic Theory of Gases

Authors: Hejie Lin, Tsung-Wu Lin
Comments: 6 Pages.

Neutrinos and molecules co-exist in space. Because both have physical properties of mass and speed, it is a logical assumption that neutrinos can interact with molecules according to the kinetic theory of gases. If neutrinos interact with gases such as nitrogen and oxygen, the mass of neutrino can be estimated using the kinetic theory of gases. According to the kinetic theory of gases, the estimated mass of a neutrino is 6.27 x 10^-38 [kg] or 0.0352 [eV/c^2]. The goal of this estimation is to predict an approximate mass of neutrinos.
Category: High Energy Particle Physics

[2] viXra:1811.0023 [pdf] submitted on 2018-11-01 08:29:32

Machine Learning Particle at LHC

Authors: George Rajna
Comments: 68 Pages.

Compared with the previous method of data pre-processing, the new machine-learning-based method has quadrupled quality metrics for the identification of particles on the calorimeter. [39] From the data collected by the LHCb detector at the Large Hadron Collider, it appears that the particles known as charm mesons and their antimatter counterparts are not produced in perfectly equal proportions. [38] The OPERA experiment, located at the Gran Sasso Laboratory of the Italian National Institute for Nuclear Physics (INFN), was designed to conclusively prove that muon-neutrinos can convert to tau-neutrinos, through a process called neutrino oscillation, whose discovery was awarded the 2015 Nobel Physics Prize. [37] The Precision Reactor Oscillation and Spectrum Experiment (PROSPECT) has completed the installation of a novel antineutrino detector that will probe the possible existence of a new form of matter. [36] The MINERvA collaboration analyzed data from the interactions of an antineutrino— the antimatter partner of a neutrino—with a nucleus. [35] The inclusion of short-range interactions in models of neutrinoless double-beta decay could impact the interpretation of experimental searches for the elusive decay. [34] The occasional decay of neutrons into dark matter particles could solve a long-standing discrepancy in neutron decay experiments. [33] The U.S. Department of Energy has approved funding and start of construction for the SuperCDMS SNOLAB experiment, which will begin operations in the early 2020s to hunt for hypothetical dark matter particles called weakly interacting massive particles, or WIMPs. [32] Thanks to low-noise superconducting quantum amplifiers invented at the University of California, Berkeley, physicists are now embarking on the most sensitive search yet for axions, one of today's top candidates for dark matter. [31]
Category: High Energy Particle Physics

[1] viXra:1811.0010 [pdf] submitted on 2018-11-01 21:06:55

On The Origin of Physical States

Authors: Wei Xu
Comments: 9 Pages. This historic artical was wrriten in 2015.

For the first time in mankind history, all properties of elementary particles are uncovered and described concisely and systematically.

Aligning with the synthesis of the virtual and physical worlds in a hierarchical taxonomy of the universe, this theory refines the topology framework of universe, and presents a new perspective of the Yin Yang natural laws that, through the processes of creation and reproduction, the fundamental elements generate an infinite series of circular objects and a Yin Yang duality of dynamic fields that are sequenced and transformed states of matter between the virtual and physical worlds.

Once virtual objects are transformed, they embody various enclaves of energy states, known as dark energy, quarks, leptons, bosons, protons, and neutrons, characterized by their incentive oscillations of timestate variables in a duality of virtual realities: energy and time, spin and charge, mass and space, symmetry and asymmetry. 

As a consequence, it derives the fully-scaled quantum properties of physical particles in accordance with numerous historical experiments, and has overcome the limitations of Heisenberg’s uncertainty principle and the Standard Model, towards concisely exploring physical nature and beyond...


Category: High Energy Particle Physics