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[20] viXra:2003.0667 [pdf] submitted on 2020-03-31 07:59:27
Authors: George Rajna
Comments: 74 Pages.
Motivating the new theory is previous PPPL research that demonstrates how the instability that was thought to lead to magnetic reconnection can, in fact, self-stabilize the plasma. [42] Whether zipping through a star or a fusion device on Earth, the electrically charged particles that make up the fourth state of matter better known as plasma are bound to magnetic field lines like beads on a string. [41] Such plasmonic resonances have significant roles in biosensing with ability to improve the resolution and sensitivity required to detect particles at the scale of the single molecule. [40] A novel quantum effect observed in a carbon nanotube film could lead to the development of unique lasers and other optoelectronic devices, according to scientists at Rice University and Tokyo Metropolitan University. [39] This "piezomagnetic" material changes its magnetic properties when put under mechanical strain. [38] Researchers have developed a new flexible sensor with high sensitivity that is designed to perform variety of chemical and biological analyses in very small spaces. [37] In a new paper published today in Science Advances, researchers under the direction of Columbia Engineering Professors Michal Lipson and Alexander Gaeta (Applied Physics and Applied Mathematics) have miniaturized dual-frequency combs by putting two frequency comb generators on a single millimeter-sized chip. [36] Researchers have, for the first time, integrated two technologies widely used in applications such as optical communications, bio-imaging and Light Detection and Ranging (LIDAR) systems that scan the surroundings of self-driving cars and trucks. [35] The unique platform, which is referred as a 4-D microscope, combines the sensitivity and high time-resolution of phase imaging with the specificity and high spatial resolution of fluorescence microscopy. [34] The experiment relied on a soliton frequency comb generated in a chip-based optical microresonator made from silicon nitride. [33] This scientific achievement toward more precise control and monitoring of light is highly interesting for miniaturizing optical devices for sensing and signal processing. [32]
Category: High Energy Particle Physics
[19] viXra:2003.0467 [pdf] submitted on 2020-03-22 14:52:34
Authors: Thomas J. Buckholtz
Comments: 85 pages
Physics theory has yet to settle on specific descriptions for new elementary particles, for dark matter, and for dark energy forces. Our work extrapolates from the known elementary particles. The work suggests well-specified candidate descriptions for new elementary particles, dark matter, and dark energy forces. This part of the work does not depend on theories of motion. This work embraces symmetries that correlate with motion-centric conservation laws. The candidate descriptions seem to explain data that prior physics theory seems not to explain. Some of that data pertains to elementary particles. Our theory suggests relationships between masses of elementary particles. Our theory suggests a relationship between the strengths of electromagnetism and gravity. Some of that data pertains to astrophysics. Our theory seems to explain ratios of dark matter effects to ordinary matter effects. Our theory seems to explain aspects of galaxy formation. Some of that data pertains to cosmology. Our theory suggests bases for inflation and for changes in the rate of expansion of the universe. Generally, our work proposes extensions to theory in three fields. The fields are elementary particles, astrophysics, and cosmology. Our work suggests new elementary particles and seems to explain otherwise unexplained data.
Category: High Energy Particle Physics
[18] viXra:2003.0457 [pdf] submitted on 2020-03-22 07:04:15
Authors: George Rajna
Comments: 78 Pages.
Creating and controlling on Earth the fusion energy that powers the sun and stars is a key goal of scientists around the world. [43] Researchers at MIT's Plasma Science and Fusion Center (PSFC) have now demonstrated how microwaves can be used to overcome barriers to steady-state tokamak operation. [42] Plasma particle accelerators more powerful than existing machines could help probe some of the outstanding mysteries of our universe, as well as make leaps forward in cancer treatment and security scanning-all in a package that's around a thousandth of the size of current accelerators. [41] The Department of Energy's SLAC National Accelerator Laboratory has started to assemble a new facility for revolutionary accelerator technologies that could make future accelerators 100 to 1,000 times smaller and boost their capabilities. [40] The authors designed a mechanism based on the deployment of a transport barrier to confine the particles and prevent them from moving from one region of the accelerator to another. "There is strong experimental evidence that there is indeed some new physics lurking in the lepton sector," Dev said. [38] Now, in a new result unveiled today at the Neutrino 2018 conference in Heidelberg, Germany, the collaboration has announced its first results using antineutrinos, and has seen strong evidence of muon antineutrinos oscillating into electron antineutrinos over long distances, a phenomenon that has never been unambiguously observed. [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
[17] viXra:2003.0444 [pdf] submitted on 2020-03-21 05:07:25
Authors: George Rajna
Comments: 80 Pages.
A team of DESY scientists has built a miniature double particle accelerator that can recycle some of the laser energy fed into the system to boost the energy of the accelerated electrons a second time. [45] As an alternative cost-cutting option to accelerate particles more efficiently, the wakefield accelerator has been suggested. Physicists send a beam of either electrons, protons, or a laser through a plasma. [44] A KAIST research team successfully identified the underlying principles behind electron heating, which is one of the most important phenomena in plasmas. [43] Researchers at MIT's Plasma Science and Fusion Center (PSFC) have now demonstrated how microwaves can be used to overcome barriers to steady-state tokamak operation. [42] Plasma particle accelerators more powerful than existing machines could help probe some of the outstanding mysteries of our universe, as well as make leaps forward in cancer treatment and security scanning-all in a package that's around a thousandth of the size of current accelerators. [41] The Department of Energy's SLAC National Accelerator Laboratory has started to assemble a new facility for revolutionary accelerator technologies that could make future accelerators 100 to 1,000 times smaller and boost their capabilities. [40] The authors designed a mechanism based on the deployment of a transport barrier to confine the particles and prevent them from moving from one region of the accelerator to another. "There is strong experimental evidence that there is indeed some new physics lurking in the lepton sector," Dev said. [38] Now, in a new result unveiled today at the Neutrino 2018 conference in Heidelberg, Germany, the collaboration has announced its first results using antineutrinos, and has seen strong evidence of muon antineutrinos oscillating into electron antineutrinos over long distances, a phenomenon that has never been unambiguously observed. [37]
Category: High Energy Particle Physics
[16] viXra:2003.0443 [pdf] submitted on 2020-03-21 05:37:30
Authors: George Rajna
Comments: 86 Pages.
It's surprising to think that the humble magnet is our gateway to some of the universe's deepest mysteries, but then again, that's the power of attraction. [46]
A team of DESY scientists has built a miniature double particle accelerator that can recycle some of the laser energy fed into the system to boost the energy of the accelerated electrons a second time. [45]
As an alternative cost-cutting option to accelerate particles more efficiently, the wakefield accelerator has been suggested. Physicists send a beam of either electrons, protons, or a laser through a plasma. [44]
Category: High Energy Particle Physics
[15] viXra:2003.0410 [pdf] submitted on 2020-03-20 10:29:46
Authors: George Rajna
Comments: 58 Pages.
Patrick Huber, a professor in the Virginia Tech Department of Physics, has co-authored an article that describes the potential uses and limitations of antineutrino detectors for nuclear security applications related to reactor, spent fuel, and explosion monitoring. [21] Technology to measure the flow of subatomic particles known as antineutrinos from nuclear reactors could allow continuous remote monitoring designed to detect fueling changes that might indicate the diversion of nuclear materials. [20] Ereditato even dreams of replacing the design of one of the four massive DUNE far detector modules with a pixelated version. [19]
Category: High Energy Particle Physics
[14] viXra:2003.0408 [pdf] submitted on 2020-03-19 12:36:00
Authors: George Rajna
Comments: 85 Pages.
We need to make the machines for the future generations, and with this technology, obviously what we can enable for the future generation is a lot." [45] As an alternative cost-cutting option to accelerate particles more efficiently, the wakefield accelerator has been suggested. Physicists send a beam of either electrons, protons, or a laser through a plasma. [44] A KAIST research team successfully identified the underlying principles behind electron heating, which is one of the most important phenomena in plasmas. [43] Researchers at MIT's Plasma Science and Fusion Center (PSFC) have now demonstrated how microwaves can be used to overcome barriers to steady-state tokamak operation. [42] Plasma particle accelerators more powerful than existing machines could help probe some of the outstanding mysteries of our universe, as well as make leaps forward in cancer treatment and security scanning-all in a package that's around a thousandth of the size of current accelerators. [41] The Department of Energy's SLAC National Accelerator Laboratory has started to assemble a new facility for revolutionary accelerator technologies that could make future accelerators 100 to 1,000 times smaller and boost their capabilities. [40] The authors designed a mechanism based on the deployment of a transport barrier to confine the particles and prevent them from moving from one region of the accelerator to another. "There is strong experimental evidence that there is indeed some new physics lurking in the lepton sector," Dev said. [38] Now, in a new result unveiled today at the Neutrino 2018 conference in Heidelberg, Germany, the collaboration has announced its first results using antineutrinos, and has seen strong evidence of muon antineutrinos oscillating into electron antineutrinos over long distances, a phenomenon that has never been unambiguously observed. [37]
Category: High Energy Particle Physics
[13] viXra:2003.0396 [pdf] submitted on 2020-03-19 05:48:36
Authors: Azadvinder Singh
Comments: 4 Pages.
In this paper, Planck particle is finally discovered.
Category: High Energy Particle Physics
[12] viXra:2003.0221 [pdf] submitted on 2020-03-10 11:52:41
Authors: George Rajna
Comments: 68 Pages.
At a seminar today at CERN, the LHCb collaboration presented a new analysis of data from a specific transformation, or "decay," that a particle called B0 meson can undergo. [41] The LHCb collaboration has reported an intriguing new result in its quest to test a key principle of the Standard Model called lepton universality. [40] Do the anomalies observed in the LHCb experiment in the decay of B mesons hide hitherto unknown particles from outside the currently valid and well-tested Standard Model? [39] "There is strong experimental evidence that there is indeed some new physics lurking in the lepton sector," Dev said. [38] Now, in a new result unveiled today at the Neutrino 2018 conference in Heidelberg, Germany, the collaboration has announced its first results using antineutrinos, and has seen strong evidence of muon antineutrinos oscillating into electron antineutrinos over long distances, a phenomenon that has never been unambiguously observed. [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]
Category: High Energy Particle Physics
[11] viXra:2003.0203 [pdf] submitted on 2020-03-10 05:38:12
Authors: Miroslav Súkeník, Jozef Šima
Comments: 2 Pages.
The existence of the Higgs boson produced by the quantum excitation of the Higgs field
was predicted in 1964. Since this year, efforts of particle physicists have focused on theoretical predictions and experimental determination of the boson mass. Several values of the mass have been published, gradually approaching 125 GeV. Applying the fundamentals of our Expansive Nondecelerative Universe model we calculated the Higgs boson’s mass as 125.39 GeV and published this result as early as May 2012. The latest evaluation (March 2020) of the data obtained at the Large Hadron Collider led to 125.38 GeV.
Category: High Energy Particle Physics
[10] viXra:2003.0175 [pdf] submitted on 2020-03-09 09:53:21
Authors: Jan Helm
Comments: 52 Pages.
This paper presents traditional and new methods and results for calculation of decay times of particles in the Standard Model.
In chapters 1 and 2 the phenomenological and the theoretical knowledge of the decays is presented, based on the literature.
In chapters 4 and 5 the interaction energy (mass-energy mX of the mediating boson in the Feynman diagram) is introduced and a characterization of the decays,
based on particle type, isospin, and interaction energy, is presented.
In chapter 6 the calculation model and the calculation results of selected typical decays are discussed.
Category: High Energy Particle Physics
[9] viXra:2003.0140 [pdf] submitted on 2020-03-07 06:51:23
Authors: George Rajna
Comments: 56 Pages.
One of the greatest mysteries in astrophysics these days is a tiny subatomic particle called a neutrino, so small that it passes through matter—the atmosphere, our bodies, the very Earth—without detection. [23]
Physicists from the Cluster of Excellence PRISMA+ at Johannes Gutenberg University Mainz (JGU) play a leading role in a new study that indicates that the puzzle of neutrino mass ordering may finally be solved in the next few years. [22]
If it turns out that neutrinos and antineutrinos oscillate in a different way from one another, this may partially account for the present-day matter–antimatter imbalance. [21]
Studying this really interesting particle that's all around us, and yet is so hard to measure, that could hold the key to understanding why we're here at all, is exciting—and I get to do this for a living," says Mauger. [20]
Category: High Energy Particle Physics
[8] viXra:2003.0134 [pdf] submitted on 2020-03-06 08:58:52
Authors: Richard L Amoroso
Comments: 26 Pages. Preprint of Chap 12: The Holographic Anthropic Multiverse Formalizing the Complex Geometry of Reality, World Scientific, https://doi.org/10.1142/7203, July 2009
Utilizing a new concept of a static (albeit relativistic) de Broglie matter-wave resonance hierarchy to coherently putatively control a highly symmetric M-Theory model of SUSY structural-phenomenology of the ‘total’ regime of spacetime, practical matter-wave antiballistic defense shield technologies appear feasible in the near term. The model although obvious to us is not based on ‘politically correct’ theory and has therefore been missed by the scientific community’s rigid adherence to myopic views of quantum theory and cosmology. In simple terms the vacuum (Dirac type), not just the superficial surface equated with the zero-point field and quantum stochasticity, but the complete HD structural regime of spacetime itself. This requires a completed form of quantum theory able to manipulate causality (surmount uncertainty through an ontological form of scale invariant conformal invariance) and utilize unitary field parameters (topological) to control constructive interference of the matter-wave resonant hierarchy. Another key element is to discard the belief that nucleons have been created at a primordial Big Bang era. Operation of the shield technologies relies on the central premise of de Broglie-Bohm modeling of quantum theory (albeit radically extended in several ways) that matter is continuously created, annihilated and recreated as physically real stationary waves imbedded in the local fabric of spacetime. We anticipate matter-wave antiballistic defense shield technologies to appear in three stages or generations: 1) Simple coherently controlled constructive interference that might strengthen aluminum to the density of depleted uranium. 2) Full incorporation of the HD SUSY properties of spacetime. 3) Mature manipulation of spacetime, nanoscale programmable matter, probable antimatter phase configurations, energy efficiency and incursive nonlinear control of the nonlocal ‘coherence-length’. From our vantage point we envision no physical reason why the 3rd generation device cannot withstand nuclear ordinance as soon as the principles outlined here are incorporated in the design of shield technologies. In this respect this chapter is a review of the various principles required for implementing matter-wave defense shield technologies rather than a complete engineering manual.
Category: High Energy Particle Physics
[7] viXra:2003.0131 [pdf] replaced on 2020-03-09 12:49:11
Authors: Ervin Goldfain
Comments: 8 Pages.
As it is known, the anomalous magnetic moment of muons is a longstanding puzzle of the Standard Model (SM). Commonly referred to as the muon “g-2 problem”, the precise testing of this anomaly provides a sensitive probe for physics beyond SM. Here we show that the leading order contribution to the muon anomaly can be estimated from the onset of non-equilibrium dynamics near the Fermi scale. The derivation is straightforward and evades the postulated existence of new phenomena in the low to the mid TeV range of high-energy physics.
Category: High Energy Particle Physics
[6] viXra:2003.0109 [pdf] submitted on 2020-03-05 14:17:54
Authors: M. A. Thomas
Comments: 23 Pages. This is a PDF of a Powerpoint Presentation (23 Slides)
This is Part II of the original presentation by the same title. In this slideshow I will attempt to extend the domain of the theory to higher energies in the extremal gravities present at ~ 2M☉ neutron stars and smaller black holes. At these higher energies and stronger gravities the theory moves into supergravity theories. These are not quantum gravities but are the lower limit of such. Extremal gravities are still comparatively weak compared to strong space-time curvatures near singularities. The Planck energies are still relatively far away and rolled up in very small compactifications. It is not currently known where the energies of supergravities lie.
Category: High Energy Particle Physics
[5] viXra:2003.0099 [pdf] submitted on 2020-03-05 04:38:42
Authors: George Rajna
Comments: 64 Pages.
State University physicists believe they have an answer to unusual incidents of rare decay of a subatomic particle called a Kaon that were reported last year by scientists in the KOTO experiment at the Japan Proton Accelerator Research Complex. [40] In an unconventional new study, a team at Chalmers University of Technology in Sweden and the Max Planck Institute for the Science of Light set out to explore the interaction between a large atom and acoustic fields with wavelengths several orders of magnitude below the atomic dimensions. [39] The researchers acknowledge that aside from the "cool" factor, their achievement may not lead to any immediate practical applications, but suggest it might help with conducting studies of photons from the sun. [38] Fiber optic gyroscopes, which measure the rotation and orientation of airplanes and other moving objects, are inherently limited in their precision when using ordinary classical light. [37] Researchers have demonstrated the first quantum light-emitting diode (LED) that emits single photons and entangled photon pairs with a wavelength of around 1550 nm, which lies within the standard telecommunications window. [36] JILA scientists have invented a new imaging technique that produces rapid, precise measurements of quantum behavior in an atomic clock in the form of near-instant visual art. [35] The unique platform, which is referred as a 4-D microscope, combines the sensitivity and high time-resolution of phase imaging with the specificity and high spatial resolution of fluorescence microscopy. [34] The experiment relied on a soliton frequency comb generated in a chip-based optical microresonator made from silicon nitride. [33] This scientific achievement toward more precise control and monitoring of light is highly interesting for miniaturizing optical devices for sensing and signal processing. [32]
Category: High Energy Particle Physics
[4] viXra:2003.0098 [pdf] submitted on 2020-03-05 05:08:07
Authors: George Rajna
Comments: 66 Pages.
A quarter-century after its discovery, physicists at the ATLAS Experiment at CERN are gaining new insight into the heaviest-known particle, the top quark. [41] Florida State University physicists believe they have an answer to unusual incidents of rare decay of a subatomic particle called a Kaon that were reported last year by scientists in the KOTO experiment at the Japan Proton Accelerator Research Complex. [40] In an unconventional new study, a team at Chalmers University of Technology in Sweden and the Max Planck Institute for the Science of Light set out to explore the interaction between a large atom and acoustic fields with wavelengths several orders of magnitude below the atomic dimensions. [39] The researchers acknowledge that aside from the "cool" factor, their achievement may not lead to any immediate practical applications, but suggest it might help with conducting studies of photons from the sun. [38] Fiber optic gyroscopes, which measure the rotation and orientation of airplanes and other moving objects, are inherently limited in their precision when using ordinary classical light. [37] Researchers have demonstrated the first quantum light-emitting diode (LED) that emits single photons and entangled photon pairs with a wavelength of around 1550 nm, which lies within the standard telecommunications window. [36] JILA scientists have invented a new imaging technique that produces rapid, precise measurements of quantum behavior in an atomic clock in the form of near-instant visual art. [35] The unique platform, which is referred as a 4-D microscope, combines the sensitivity and high time-resolution of phase imaging with the specificity and high spatial resolution of fluorescence microscopy. [34] The experiment relied on a soliton frequency comb generated in a chip-based optical microresonator made from silicon nitride. [33] This scientific achievement toward more precise control and monitoring of light is highly interesting for miniaturizing optical devices for sensing and signal processing. [32]
Category: High Energy Particle Physics
[3] viXra:2003.0089 [pdf] submitted on 2020-03-03 22:00:25
Authors: Adham ahmed Mohamed ahmed
Comments: 1 Page. Ty
rest mass energy can double up(out of no where) to both rest mass energy and kinetic energy(or any other type of energy as an extension to the theory) at the existence of another rest mass near it(which will double up its energy too)
The reason why this happens is very simple the two masses have energy and so they act up upon each other
requirements for possible inventions: It's up to you to find out why does the mass doubles out of no where when it's energy around other masses
proofs:1.E=mc^2
2.The fact that two masses don't change their push when increasing their masses if the two masses are always equal and if you decrease one mass and increase other they always give the velocity multiplicative to their mass
Category: High Energy Particle Physics
[2] viXra:2003.0026 [pdf] replaced on 2020-03-03 09:10:46
Authors: Sylwester Kornowski
Comments: 3 Pages.
The measured production cross sections of top quark pairs in association with two b jets in proton-proton collisions at sqrt(s) = 13 TeV by the CMS detector at the LHC are found to be larger than theoretical productions by a factor of 1.5-2.4, corresponding to 1-2 standard deviations. Here we show that this discrepancy is due to the omission of the real baryon structure described in the Scale-Symmetric Theory. The properties of the scalar condensate in the centre of baryons and the spacetime mass of gluons are the keys to understanding the observed discrepancy.
Category: High Energy Particle Physics
[1] viXra:2003.0001 [pdf] submitted on 2020-03-01 10:27:49
Authors: Rafael Cañete Mesa
Comments: 16 Pages. 5 figures; Including Spanish version
In this article we present only one physical relation, and prove that it is sufficient to justify the entire spectrum of fundamental particles of matter (fermions), that is, the hierarchical division of their generations, the value of their masses and the distances among them. This relation also makes up a method or tool to discriminate which elementary particles are possible and not, and the exact mass value of the existing ones. According to this scheme, we prove that there has to exist a particle M=171.87 eV, or an equivalent energy entity, which represents a common zero generation to quarks and charged leptons, and a mediator particle in the connection of these with neutrinos, for which, by applying this methodology, we obtain a massive base consistent with the theoretical and experimental requirements for neutrino oscillation.
Category: High Energy Particle Physics
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