High Energy Particle Physics

1609 Submissions

[18] viXra:1609.0436 [pdf] submitted on 2016-09-30 07:30:59

Photon Scalar/Pseudoscalar Mixing Dynamics In Magnetized Media

Authors: Manoj K. Jaiswal, Avijit K. Ganguly
Comments: 3 Pages. A short report

We study the dynamics of photon-scalar interaction (mixing) by operators of mass dimension five (predicted in numerous theories, beyond standard model), in various kinds of media. Our main objectives are to study medium specific modifications to the mixing dynamics of of photons with pseudoscalar (axion a(x)) and scalar e.g., dilaton , moduli etc. (denoted by φ(x)) dark matter candidates. We look into spectro-polarimetric as well as oscillation aspects of the same and their possible astrophysical consequences.
Category: High Energy Particle Physics

[17] viXra:1609.0429 [pdf] replaced on 2016-10-01 21:49:02

On a New Method to Detect Neutrinos

Authors: Zhi Cheng
Comments: 16 Pages. 5 Figures; Include Chinese version

I proposed a new method to detect the neutrinos. The characteristic of this new method is to make use of the interactions between electron and neutrino. These interactions will produce the W bosons and etc. The produced W bosons will decay to pairs of lepton and neutrino. Then we only need to detect the leptons produced by W bosons to make sure how many neutrinos had arrived.
Category: High Energy Particle Physics

[16] viXra:1609.0422 [pdf] replaced on 2016-10-11 10:11:21

Geometric Clifford Algebra and Quantum Interpretation of the Proton's Anomalous Magnetic Moment (poster)

Authors: Michaele Suisse, Peter Cameron
Comments: Pages.

The role of the anomalous moment in the geometric algebra of proton topological mass generation suggests that the anomaly is not an intrinsic property of the free space proton, but rather a topological effect of applying the electromagnetic bias field required to define the eigenstates probed by the magnetic moment measurement. Quantum interpretations strive to explain emergence of the world we observe from formal quantum theory. This variant on the canonical measurement problem is examined in the larger context of quantum interpretations. A more detailed presentation of this content may be found here: https://www.youtube.com/watch?v=uyM4cZgSprI
Category: High Energy Particle Physics

[15] viXra:1609.0396 [pdf] replaced on 2016-10-03 05:52:05

The Higgs Boson and the Alternative Charge Carriers: Part III

Authors: John A. Gowan
Comments: 6 Pages. In three parts due to length. Adding closing statement.

The four forces of physics are considered in terms of the broken symmetry of our "matter only" Universe
Category: High Energy Particle Physics

[14] viXra:1609.0359 [pdf] submitted on 2016-09-25 14:40:38

Physical Model of a Real Photon with Substructure and Mass

Authors: Kenneth D. Oglesby
Comments: 7 Pages. Related to MC Physics or Mono-Charge Physics theories

A physical model of a photon with substructure and mass is presented that satisfies all known properties and characteristics of photons. The model shows that relativistic enhanced rotating mono-charges cause the EMF signature of light, scattering effects, gravity affects, and momentum/ kinetic energy. A photon's kinetic energy (KE) includes both linear KE from its mass travelling at the average speed of light, c, and its rotational KE from instant mass rotating at the frequency required velocity.
Category: High Energy Particle Physics

[13] viXra:1609.0342 [pdf] submitted on 2016-09-24 02:52:09

Lepton Flavor Violation

Authors: George Rajna
Comments: 15 Pages.

The Standard Model allows for the Higgs boson to decay to identically flavored pairs of leptons, such as electrons and muons, but not to mixed pairings of lepton flavors. Evidence of the latter would be a sign of new physics. [14] It may only take scientists a few more years to solve one of the biggest puzzles in modern elementary particle physics, the so-called "muon mystery." Russian scientists from the National Research Nuclear University (MEPhI) will make a significant contribution to this research. [13] A large team made up of researchers from across the globe has repeated experiments conducted several years ago that showed a different radius for a proton when it was orbited by a muon as opposed to an electron—a finding dubbed the proton radius puzzle—using a deuterium nucleus this time and has found the same puzzle. In their paper published in the journal Science, the team describes the experiments they conducted, what they found and offer a few possible ideas to help dispel the notion that the puzzle indicates that there may be some problems with the Standard Model. [12] The resolution of the Proton Radius Puzzle is the diffraction pattern, giving another wavelength in case of muonic hydrogen oscillation for the proton than it is in case of normal hydrogen because of the different mass rate. Taking into account the Planck Distribution Law of the electromagnetic oscillators, we can explain the electron/proton mass rate and the Weak and Strong Interactions. Lattice QCD gives the same results as the diffraction patterns of the electromagnetic oscillators, explaining the color confinement and the asymptotic freedom of the Strong Interactions.
Category: High Energy Particle Physics

[12] viXra:1609.0303 [pdf] submitted on 2016-09-20 22:38:05

Is there Proton Neutrino

Authors: Zhi Cheng
Comments: 6 Pages. Include Chinese version

This work based on my previous works. I postulate that there is proton neutrino just like electron neutrino since protons are also the elementary particles just like electrons. Then I point out that there must be proton meson that consisted with proton and proton neutrino. In this paper, I analysis the proton meson’s decay model by diagrammatic scheme. I also calculate some parameters of proton meson, and give some advises on how to detect these particles.
Category: High Energy Particle Physics

[11] viXra:1609.0298 [pdf] submitted on 2016-09-20 09:37:38

“The Road to Understanding of Neutrinos – the Hidden Truth About Neutrinos and Other “quanticles““

Authors: Imrich Krištof
Comments: 21 Pages.

This actual submitted publication refers about recent facts and phenomenas, elusive or real particles called neutrinos. During last few months was revealed in giant neutrino's projects in Europe–CERN–LHC (Large Hadron Collider) ATLAS DETECTOR and in MINOS EXPERIMENT / MAIN INJECTOR NEUTRINO OSCILLATION SEARCH) Fermilab NUMI / Illinois near Chicago, U.S.A. many new realities about these elementary nuclear particles, which consists of whole cosmic matter. Were studied and observed properties of neutrinos, like emission, oscillation (Nobel Prize for Physics 2015), detection and the most interesting (qm) superposition in Project MINOS (735 km of distance between place with Detector 1 in Fermilab and place with Detector 2 in Soudan), under leading of David Kaiser from M.I.T. / Massachussett's Institute of Technology) in Cambridge, U.S.A. D. Kaiser easily said: “The particles neutrinos can existed in many quantum states at the same time.“ According this theory, particles neutrinos can rotate according direction of clocks hands and against their direction at the same time, or could be together nonexcited and excitated. About (QM) SUPERPOSITION before 100 years was reflected already Erwin Schrödinger in mind–experiment the Schrödinger's cat. In July's number of Journal Physical Review Letters, Physicist David Kaiser and his team studied distribution of all types of neutrinos produced in Chicago's Fermilab and compared it with distribution of all types on neutrinos detected in Soudan. Finally they had come to believe that, observed particles distributions are the best explanated, that neutrinos are during the flight between Chicago's Fermilab and Mine Soudan, in MINNESOTA, in state known like quantum-mechanic superposition, and not take resemblence of one's concretely type of neutrino. From upper sets realities are offered questions like “are neutrinos immortal or like hologram“. Further parts of this article is dedicated to summarizing of data from Superkamiokande and Sudbury Neutrino Observatory (Nobel Prize for Physics 2015), and emission and detection of neutrinos and other “quanticles“ defined by principles of Prof. Joseph Weber and other scientists. In the ending part of this article is dedicated a chapter to theory of Fermi's Golden Rule (respectively neutrino–antineutrino cross section).
Category: High Energy Particle Physics

[10] viXra:1609.0224 [pdf] replaced on 2017-08-30 12:41:42

Alternative Charge Carriers and the Higgs Boson: Part II

Authors: John A. Gowan
Comments: 6 Pages. part 2 of 3

Abstract A functional class of particles, the "Alternative Charge Carriers" (ACCs), is recognized as characteristic of the Electroweak domain and the Weak Force Intermediate Vector Bosons (IVBs). Using a financial analogy, the weak force mechanism is compared to the operation of a government mint.
Category: High Energy Particle Physics

[9] viXra:1609.0223 [pdf] submitted on 2016-09-15 01:38:05

Laser Diffraction Proton Acceleration

Authors: George Rajna
Comments: 15 Pages.

A targeted way to manipulate beams of protons accelerated using ultrashort and ultraintense laser pulses has been demonstrated by a team of researchers led at the University of Strathclyde. [12] The work elucidates the interplay between collective and single-particle excitations in nuclei and proposes a quantitative theoretical explanation. It has as such great potential to advance our understanding of nuclear structure. [11] When two protons approaching each other pass close enough together, they can " feel " each other, similar to the way that two magnets can be drawn closely together without necessarily sticking together. According to the Standard Model, at this grazing distance, the protons can produce a pair of W bosons. [10] The fact that the neutron is slightly more massive than the proton is the reason why atomic nuclei have exactly those properties that make our world and ultimately our existence possible. Eighty years after the discovery of the neutron, a team of physicists from France, Germany, and Hungary headed by Zoltán Fodor, a researcher from Wuppertal, has finally calculated the tiny neutron-proton mass difference. [9] Taking into account the Planck Distribution Law of the electromagnetic oscillators, we can explain the electron/proton mass rate and the Weak and Strong Interactions. Lattice QCD gives the same results as the diffraction patterns of the electromagnetic oscillators, explaining the color confinement and the asymptotic freedom of the Strong Interactions.
Category: High Energy Particle Physics

[8] viXra:1609.0214 [pdf] submitted on 2016-09-14 03:53:32

On Generations in Elementary Particle Physics

Authors: Paul R. Gerber
Comments: 2 Pages.

Elementary Fermions come in generations, e.g. (electron, muon, tau), neutrino-triplet, etc., which is an experimental fact and sometimes apostrophized as a mystery [1] because a theoretical explanation is missing. That there are more than three generations is considered possible but unlikely. We show that generations follow from group-theoretical arguments and that their number is determined by the number of space dimensions.
Category: High Energy Particle Physics

[7] viXra:1609.0182 [pdf] submitted on 2016-09-13 03:16:30

Nucleus Excitations

Authors: George Rajna
Comments: 14 Pages.

The work elucidates the interplay between collective and single-particle excitations in nuclei and proposes a quantitative theoretical explanation. It has as such great potential to advance our understanding of nuclear structure. [11] When two protons approaching each other pass close enough together, they can “feel” each other, similar to the way that two magnets can be drawn closely together without necessarily sticking together. According to the Standard Model, at this grazing distance, the protons can produce a pair of W bosons. [10] The fact that the neutron is slightly more massive than the proton is the reason why atomic nuclei have exactly those properties that make our world and ultimately our existence possible. Eighty years after the discovery of the neutron, a team of physicists from France, Germany, and Hungary headed by Zoltán Fodor, a researcher from Wuppertal, has finally calculated the tiny neutron-proton mass difference. [9] Taking into account the Planck Distribution Law of the electromagnetic oscillators, we can explain the electron/proton mass rate and the Weak and Strong Interactions. Lattice QCD gives the same results as the diffraction patterns of the electromagnetic oscillators, explaining the color confinement and the asymptotic freedom of the Strong Interactions.
Category: High Energy Particle Physics

[6] viXra:1609.0116 [pdf] replaced on 2016-09-18 22:00:53

The Diagrams of Particles Decay Process and the Prediction of New Particle

Authors: Zhi Cheng
Comments: 16 Pages. Include Chinese Version

I have proposed an intuitive diagrammatic method to explore the elementary particles’ structures and decay processes based on virtual space-time. Then I discuss the possibilities of the existing of new particles. I also raised some issues that need to attention when probing those new particles.
Category: High Energy Particle Physics

[5] viXra:1609.0110 [pdf] submitted on 2016-09-08 22:02:39

Quantum Hall Effect for Dyons

Authors: Pawan Kumar Joshi, O.P.S.Negi
Comments: 16 Pages.

Considering the generalized charge and generalized four potential associated of dyons as complex quantities with their real and imaginary parts as electric and magnetic constituents, in this present discussion we have constructed a gauge covariant and rotational symmetric angular momentum operator for dyons in order to analyze the integer and fractional quantum Hall effect. It has been shown that the commutation relations of angular momentum operator possesses a higher symmetry to reproduce the eigen values and eigen function Lowest Landau Level (LLL) for quantum Hall system. The LLL has also been constructed in terms of I^{st} Hopf map \left(S^{3}\rightarrow S^{2}\right) and it is concluded that dyons are more suitable object to investigate the existence of quantum Hall effect (both integer and fractional )
Category: High Energy Particle Physics

[4] viXra:1609.0101 [pdf] submitted on 2016-09-08 09:41:00

Hypothetical New Particle

Authors: George Rajna
Comments: 16 Pages.

The physicists describe the hypothetical new particle as an "electrophobic scalar boson." Currently there are five bosons in the standard model, only one of which is a scalar (the Higgs), meaning it has zero spin. All five bosons have been experimentally confirmed, and all are force carriers that play a role in holding matter together. [14] It may only take scientists a few more years to solve one of the biggest puzzles in modern elementary particle physics, the so-called "muon mystery." Russian scientists from the National Research Nuclear University (MEPhI) will make a significant contribution to this research. [13] A large team made up of researchers from across the globe has repeated experiments conducted several years ago that showed a different radius for a proton when it was orbited by a muon as opposed to an electron—a finding dubbed the proton radius puzzle—using a deuterium nucleus this time and has found the same puzzle. In their paper published in the journal Science, the team describes the experiments they conducted, what they found and offer a few possible ideas to help dispel the notion that the puzzle indicates that there may be some problems with the Standard Model. [12] The resolution of the Proton Radius Puzzle is the diffraction pattern, giving another wavelength in case of muonic hydrogen oscillation for the proton than it is in case of normal hydrogen because of the different mass rate. Taking into account the Planck Distribution Law of the electromagnetic oscillators, we can explain the electron/proton mass rate and the Weak and Strong Interactions. Lattice QCD gives the same results as the diffraction patterns of the electromagnetic oscillators, explaining the color confinement and the asymptotic freedom of the Strong Interactions.
Category: High Energy Particle Physics

[3] viXra:1609.0092 [pdf] submitted on 2016-09-07 22:17:34

Beyond Quantum Fields: A Classical Fields Approach to QED

Authors: Clifford E Chafin
Comments: 13 Pages.

A classical field theory is introduced that is defined on a tower of dimensionally increasing spaces and is argued to be equivalent to QED. The domain of dependence is discussed to show how an equal times picture of the many coordinate space gives QED results as part of a well posed initial value formalism. Identical particle symmetries are not, a priori, required but when introduced are clearly propagated. This construction uses only classical fields to provide some explanation for why quantum fields and canonical commutation results have been successful. Some old and essential questions regarding causality of propagators are resolved. The problem of resummation, generally forbidden for conditionally convergent series, is discussed from the standpoint of particular truncations of the infinite tower of functions and a two step adiabatic turn on for scattering. As a result of this approach it is shown that the photon inherits its quantization \hbar ω from the free lagrangian of the Dirac electrons despite the fact that the free electromagnetic lagrangian has no hbar in it. This provides a possible explanation for the canonical commutation relations for quantum operators, [P,Q] = i hbar without ever needing to invoke such a quantum postulate. The form of the equal times conservation laws in this many particle field theory suggests a simplification of the radiation reaction process for fields that allows QED to arise from a sum of path integrals in the various particle time coordinates. A novel method of unifying this theory with gravity, but that has no obvious quantum field theoretic computational scheme, is introduced.
Category: High Energy Particle Physics

[2] viXra:1609.0076 [pdf] submitted on 2016-09-06 13:12:03

Madala Boson of Dark Matter

Authors: George Rajna
Comments: 21 Pages.

Scientists at the High Energy Physics Group (HEP) of the University of the Witwatersrand in Johannesburg predict the existence of a new boson that might aid in the understanding of Dark Matter in the Universe. [15] For decades, researchers have tried to detect this invisible dark matter. Several types of devices have been put up on Earth and in space to capture the particles that dark matter is supposed to consist of, and experiments have attempted to create a dark matter particle by colliding ordinary matter particles at very high temperatures. [13] " Call it the sound of dark matter, " says Asimina Arvanitaki, a theoretical particle physicist at Perimeter Institute. Despite making up the vast majority of stuff in our universe, dark matter remains invisible. But perhaps it's not inaudible. Dark matter is some of the most abundant, yet most elusive, stuff in the universe. Though scientists are confident it is out there (thanks to the gravitational effects it has on its surroundings), the search to identify it has thus far come up empty. [12] An international team of scientists using a combination of radio and optical telescopes has for the first time managed to identify the location of a fast radio burst, allowing them to confirm the current cosmological model of the distribution of matter in the universe. [11] Invisibility — like time travel, teleportation, flying, and super-speed — has been a fixture in science fiction ever since science fiction has existed. The most well-known examples range from the one used by the Romulans in Star Trek, Harry Potter's deathly hallows cloaking device, and the eleven cloak Frodo and Sam used to evade Sauron's army at the gates of Mordor. There are hundreds, if not thousands, of other mentions in books, movies and television. Over the years, many scientists have come up with inventive ways to hide objects from sight (one includes a 3D printer); only the process is certainly much more complex than science fiction makes it look. [10] The gravitational force attracting the matter, causing concentration of the matter in a small space and leaving much space with low matter concentration: dark matter and energy. There is an asymmetry between the mass of the electric charges, for example proton and electron, can understood by the asymmetrical Planck Distribution Law. This temperature dependent energy distribution is asymmetric around the maximum intensity, where the annihilation of matter and antimatter is a high probability event. The asymmetric sides are creating different frequencies of electromagnetic radiations being in the same intensity level and compensating each other. One of these compensating ratios is the electron – proton mass ratio. The lower energy side has no compensating intensity level, it is the dark energy and the corresponding matter is the dark matter.
Category: High Energy Particle Physics

[1] viXra:1609.0013 [pdf] submitted on 2016-09-01 10:58:22

Musical Chairs of the Constants

Authors: Vito R. D'Angelo
Comments: 2 Pages.

It is demonstrated that constants (and groupings of constants)are ratios, with theoretically inherent exact values. Based on the exact value of the speed of light in vacuum, as defined by the National Institute of Standards and Technology, CODATA value: 299792458.
Category: High Energy Particle Physics