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[16] viXra:2005.0291 [pdf] submitted on 2020-05-31 21:27:53
Authors: Cesar B. Pronin, Andrey V. Ostroukh
Comments: 13 Pages.
The paper contains a research about using known classical circuit concepts as a part of quantum algorithms, keeping the benefits of both types of circuits. This was established by interpreting classical logic elements with quantum gates. Results of this research can stimulate the implementation of quantum computing in various fields of economy.
Category: Quantum Physics
[15] viXra:2005.0285 [pdf] replaced on 2020-06-02 00:21:32
Authors: Ervin Goldfain
Comments: 6 Pages.
Iterations of continuous maps are the simplest models of generic dynamical systems. In particular, circle maps display several key properties of complex dynamics, such as phase-locking and the quasi-periodicity route to chaos. Our work points out that Planck’s constant may be derived from the scaling behavior of circle maps in the asymptotic limit.
Category: Quantum Physics
[14] viXra:2005.0241 [pdf] submitted on 2020-05-24 17:16:42
Authors: Andrei Lucian Dragoi
Comments: (EpiphenEMF - v.1.0 - 23.05.2020 - 7 A4 pages)
This article argues that the electromagnetic field (EMF) might be an epiphenomenon caused by the gravitational field (GF). This paper continues (from alternative angles of view) the work of other past articles/preprints of the same author
Category: Quantum Physics
[13] viXra:2005.0192 [pdf] submitted on 2020-05-19 09:57:37
Authors: Victor Christianto, Florentin Smarandache, Yunita Umniyati
Comments: 7 Pages. This paper has been accepted and published by AIP Conference Proceedings 2234, 040008 (2020).
From time to time, some eminent physicists commenced to ask: What is the reality behind quantum mechanical predictions? Is there a realism interpretation of Quantum Physics? This paper is intended to explore such a possibility of a realism interpretation of QM, based on a derivation of Maxwell equations in Quaternion Space. In this regards, we begin with Quaternion space and its respective Quaternion Relativity (it also may be called as Rotational Relativity) as it has been discussed in several papers including [1]. The purpose of the present paper is to review our previous derivation of Maxwell equations in Q-space [17], with discussion on some implications. First, we will review our previous results in deriving Maxwell equations using Dirac decomposition, introduced by Gersten (1999). Then we will shortly make a few remark on helical solutions of Maxwell equations, Smarandache’s Hypothesis and possible cosmological entanglement. Further observations are of course recommended to refute or verify some implications of this proposition.
Category: Quantum Physics
[12] viXra:2005.0190 [pdf] replaced on 2020-06-01 16:22:58
Authors: Jean Louis Van Belle
Comments: 25 Pages.
This paper summarizes the basic principles of the common-sense interpretation of quantum physics that we have been exploring over the past few years. We also touch on some areas we did not explore before. We note, for example, that the ring current model of matter-particles must also come with a dynamic view of the fields surrounding charged particles. Potential barriers -or their corollary: potential wells – should, therefore, not be thought of as static fields: they vary in time. They result from two or more charges moving around and creating some
joint or superposed field. Hence, a particle breaking through a ‘potential wall’ or coming out of a potential ‘well’ probably just uses an opening which corresponds to a classical trajectory. This should offer a new perspective on the foundations of quantum mechanics.
Category: Quantum Physics
[11] viXra:2005.0167 [pdf] submitted on 2020-05-16 07:00:19
Authors: J.A.J. van Leunen
Comments: 17 Pages. This is part of the Hilbert Book Model Project
This is the text that is read aloud in the Base_Model PowerPoint presentation
The extra punctuation is used by the Zamzar.com utility to enter silent spaces into the text.
The conversion of the PowerPoint presentation to mp4 format introduces some inconsistencies that are difficult to prevent.
The numbers in the text relate to the slide numbers.
Category: Quantum Physics
[10] viXra:2005.0137 [pdf] replaced on 2020-05-14 08:23:53
Authors: Jean Louis Van Belle
Comments: No. of pages includes title page with summary and ToC
This paper further explores intuitions we highlighted in previous papers already:
1. The concept of the matter-wave traveling through the vacuum, an atomic lattice or any medium can be equated to the concept of an electric or electromagnetic signal traveling through the same medium.
2. There is no need to model the matter-wave as a wave packet: a single wave – with a precise frequency and a precise wavelength – will do.
3. If we do want to model the matter-wave as a wave packet rather than a single wave with a precisely defined frequency and wavelength, then the uncertainty in such wave packet reflects our own limited knowledge about the momentum and/or the velocity of the particle that we think we are representing. The uncertainty is, therefore, not inherent to Nature, but to our limited knowledge about the initial conditions.
4. The fact that such wave packets usually dissipate very rapidly, reflects that even our limited knowledge about initial conditions tends to become equally rapidly irrelevant. Indeed, as Feynman puts it, “the tiniest irregularities” tend to get magnified very quickly at the micro-scale.
In short, as Hendrik Antoon Lorentz noted a few months before his demise, there is no reason whatsoever “to elevate indeterminism to a philosophical principle.”
Category: Quantum Physics
[9] viXra:2005.0093 [pdf] submitted on 2020-05-07 13:19:14
Authors: Yi Cao
Comments: 18 Pages.
In SunQM-4, to build a full-QM deduced Solar system’s 3D probability density map with time-dependent orbital movement, we developed a non-Born probability (NBP) method. In the current paper, we showed that NBP is directly proportional to the wave function (rather than Born probability’s conjugated-squared wave function). For a cos(x) wave function, its NBP is simply to lift-up wave function by one to make its min =0, and then divided by two to make its max =1, so its NBP = [1 + cos(x)]/2. The trigonometric formula [1 + cos(x)]/2 = [cos(x/2)}^2 revealed that for a planet doing orbital movement in Solar system, its NBP ground state is n=1, and its Born probability ground state is n = 1/2. We showed that NBP is valid not only for {N,n} QM’s nLL QM state, but also for the 1D infinity deep square potential well QM, for the circular 1D QM, and for the plane wave QM. NBP demonstrates more direct and intuitive physical meaning than that of Born probability. In contrast to that Born probability is only for the standing wave function, NBP is for a uni-directional traveling wave function (which naturally includes the linearly combined two opposite-directional traveling waves, or a standing wave). Therefore, Born probability is possible merely a special case of (the more generalized) NBP. With NBP, we may explain the flute sound wave (an air mass density vibration) mechanics directly as the 1D quantum mechanics! This may significantly change our view on QM and its application on our daily-life-world’s (Newtonian) physics. The planet formation through accretion is also discussed by using NBP.
Category: Quantum Physics
[8] viXra:2005.0087 [pdf] replaced on 2020-05-09 08:18:13
Authors: Jean Louis Van Belle
Comments: 22 Pages.
This paper explores the assumptions underpinning de Broglie’s concept of a wave-packet and the various conceptual questions and issues. It also explores how the alternative – the ring current model of an electron (or of matter-particles in general) – relates to Louis de Broglie’s λ = h/p relation and rephrases the theory in terms of the wavefunction as well as the wave equation(s) for an electron in free space.
Category: Quantum Physics
[7] viXra:2005.0080 [pdf] submitted on 2020-05-05 22:34:03
Authors: Kazufumi Sakai
Comments: 8 Pages. Journal for Foundations and Applications of Physics, vol. 7, No. 1 (2020)
The quantum interference phenomenon was observed in Young’s double-slit experiment using a single photon, and then, the validity of quantum mechanics was demonstrated. However, the reason these fringes appear has not been completely explained yet because photon motion has not been investigated in detail. We found a method to observe the motion of photons using the properties of optical fibers and showed vector diagrams of the photon motion near the double-slit. The photons gradually changed their direction while intersecting and formed interference fringes. In addition, utilizing the mode property of the fiber, we observed fringes at its output end, even when one of the two interfering waves could not transmit through the fiber.
Category: Quantum Physics
[6] viXra:2005.0046 [pdf] replaced on 2020-05-05 15:58:02
Authors: Jean Louis Van Belle
Comments: 20 Pages.
In this paper, we pick some less well-known contributions of great minds to the history of ideas from the proceedings of the Solvay Conferences. We hope to show there was nothing inevitable about the new physics winning out. In fact, we suggest modern-day physicists may usefully go back to some of the old ideas – most notably the idea that elementary particles do have some shape and size – and that they should, perhaps, try somewhat harder to explain intrinsic properties of these particles, such as angular momentum and their magnetic moment, in terms of classical physics. The contributions which we discuss are those of Ernest Rutherford, Joseph Larmor, Hendrik Antoon Lorentz and Louis de Broglie.
Category: Quantum Physics
[5] viXra:2005.0022 [pdf] submitted on 2020-05-01 09:53:43
Authors: George Rajna
Comments: 57 Pages.
At the Paul Scherrer Institute PSI, researchers have gained insights into a promising material for organic light-emitting diodes (OLEDs). [36] Scientists at Tokyo Institute of Technology have fabricated a multiplexer/demultiplexer module based on a property of light that was not being exploited in communications systems: the optical vortex. [35] Optical chips are still some way behind electronic chips, but we're already seeing the results and this research could lead to a complete revolution in computer power. [34] Electronics could work faster if they could read and write data at terahertz frequency, rather than at a few gigahertz. [33] A team of researchers led by the Department of Energy's Oak Ridge National Laboratory has demonstrated a new method for splitting light beams into their frequency modes. [32] Quantum communication, which ensures absolute data security, is one of the most advanced branches of the "second quantum revolution". [31] Researchers at the University of Bristol's Quantum Engineering Technology Labs have demonstrated a new type of silicon chip that can help building and testing quantum computers and could find their way into your mobile phone to secure information. [30] Theoretical physicists propose to use negative interference to control heat flow in quantum devices. [29] Particle physicists are studying ways to harness the power of the quantum realm to further their research. [28] A fundamental barrier to scaling quantum computing machines is "qubit interference." In new research published in Science Advances, engineers and physicists from Rigetti Computing describe a breakthrough that can expand the size of practical quantum processors by reducing interference. [26]
Category: Quantum Physics
[4] viXra:2005.0016 [pdf] submitted on 2020-05-01 01:11:16
Authors: George Rajna
Comments: 39 Pages.
The groundbreaking discovery of an optical version of quantum hall effect (QHE), published today in Physical Review X, demonstrates the leadership of Rensselaer in this vital research field. [30] A workshop on exploring extreme-field QED and the physics phenomena it creates will be held at SLAC in late summer. [29] University of Toronto Engineering researchers have combined two emerging technologies for next-generation solar power-and discovered that each one helps stabilize the other. [28] Photoresponsive flash memories made from organic field-effect transistors (OFETs) that can be quickly erased using just light might find use in a host of applications, including flexible imaging circuits, infra-red sensing memories and multibit-storage memory cells. [27] Recent research from Kumamoto University in Japan has revealed that polyoxometalates (POMs), typically used for catalysis, electrochemistry, and photochemistry, may also be used in a technique for analyzing quantum dot (QD) photoluminescence (PL) emission mechanisms. [26] Researchers have designed a new type of laser called a quantum dot ring laser that emits red, orange, and green light. [25] The world of nanosensors may be physically small, but the demand is large and growing, with little sign of slowing. [24] In a joint research project, scientists from the Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy (MBI), the Technische Universität Berlin (TU) and the University of Rostock have managed for the first time to image free nanoparticles in a laboratory experiment using a highintensity laser source. [23] For the first time, researchers have built a nanolaser that uses only a single molecular layer, placed on a thin silicon beam, which operates at room temperature. [22] A team of engineers at Caltech has discovered how to use computer-chip manufacturing technologies to create the kind of reflective materials that make safety vests, running shoes, and road signs appear shiny in the dark. [21] In the September 23th issue of the Physical Review Letters, Prof. Julien Laurat and his team at Pierre and Marie Curie University in Paris (Laboratoire Kastler Brossel-LKB) report that they have realized an efficient mirror consisting of only 2000 atoms. [20]
Category: Quantum Physics
[3] viXra:2005.0011 [pdf] submitted on 2020-05-01 05:17:09
Authors: George Rajna
Comments: 20 Pages.
Researchers at Stanford University have recently carried out an in-depth study of nematic transitions in iron pnictide superconductors. [30] Using a clever technique that causes unruly crystals of iron selenide to snap into alignment, Rice University physicists have drawn a detailed map that reveals the "rules of the road" for electrons both in normal conditions and in the critical moments just before the material transforms into a superconductor. [29] Superconducting quantum microwave circuits can function as qubits, the building blocks of a future quantum computer. [28] Physicists have shown that superconducting circuits-circuits that have zero electrical resistance-can function as piston-like mechanical quantum engines. The new perspective may help researchers design quantum computers and other devices with improved efficiencies. [27] This paper explains the magnetic effect of the superconductive current from the observed effects of the accelerating electrons, causing naturally the experienced changes of the electric field potential along the electric wire. The accelerating electrons explain not only the Maxwell Equations and the Special Relativity, but the Heisenberg Uncertainty Relation, the wave particle duality and the electron's spin also, building the bridge between the Classical and Quantum Theories. The changing acceleration of the electrons explains the created negative electric field of the magnetic induction, the Higgs Field, the changing Relativistic Mass and the Gravitational Force, giving a Unified Theory of the physical forces. Taking into account the Planck Distribution Law of the electromagnetic oscillators also, we can explain the electron/proton mass rate and the Weak and Strong Interactions. Since the superconductivity is basically a quantum mechanical phenomenon and some entangled particles give this opportunity to specific matters, like Cooper Pairs or other entanglements, as strongly correlated materials and Exciton-mediated electron pairing, we can say that the secret of superconductivity is the quantum entanglement.
Category: Quantum Physics
[2] viXra:2005.0008 [pdf] submitted on 2020-05-01 06:45:23
Authors: George Rajna
Comments: 22 Pages.
A team of physicists detected superconducting currents-the flow of electrons without wasting energy-along the exterior edge of a superconducting material. [31] Researchers at Stanford University have recently carried out an in-depth study of nematic transitions in iron pnictide superconductors. [30] Using a clever technique that causes unruly crystals of iron selenide to snap into alignment, Rice University physicists have drawn a detailed map that reveals the "rules of the road" for electrons both in normal conditions and in the critical moments just before the material transforms into a superconductor. [29] Superconducting quantum microwave circuits can function as qubits, the building blocks of a future quantum computer. [28] Physicists have shown that superconducting circuits-circuits that have zero electrical resistance-can function as piston-like mechanical quantum engines. The new perspective may help researchers design quantum computers and other devices with improved efficiencies. [27] This paper explains the magnetic effect of the superconductive current from the observed effects of the accelerating electrons, causing naturally the experienced changes of the electric field potential along the electric wire. The accelerating electrons explain not only the Maxwell Equations and the Special Relativity, but the Heisenberg Uncertainty Relation, the wave particle duality and the electron's spin also, building the bridge between the Classical and Quantum Theories. The changing acceleration of the electrons explains the created negative electric field of the magnetic induction, the Higgs Field, the changing Relativistic Mass and the Gravitational Force, giving a Unified Theory of the physical forces. Taking into account the Planck Distribution Law of the electromagnetic oscillators also, we can explain the electron/proton mass rate and the Weak and Strong Interactions. Since the superconductivity is basically a quantum mechanical phenomenon and some entangled particles give this opportunity to specific matters, like Cooper Pairs or other entanglements, as strongly correlated materials and Exciton-mediated electron pairing, we can say that the secret of superconductivity is the quantum entanglement.
Category: Quantum Physics
[1] viXra:2005.0001 [pdf] submitted on 2020-05-01 08:45:41
Authors: George Rajna
Comments: 41 Pages.
A large international team of researchers has improved upon Primakoff-type experiments to give an improved accuracy of pion measurement. [28]
In 1973, Russian physicist A.B. Migdal predicted the phenomenon of pion condensation above a critical, extremely high—several times higher than that for normal matter— nuclear density. [27]
Our first glimpses into the physics that exist near the center of a black hole are being made possible using "loop quantum gravity"—a theory that uses quantum mechanics to extend gravitational physics beyond Einstein's theory of general relativity. [26]
Category: Quantum Physics
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