International Journal of Physics
ISSN (Print): 2333-4568 ISSN (Online): 2333-4576 Website: http://www.sciepub.com/journal/ijp Editor-in-chief: B.D. Indu
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International Journal of Physics. 2018, 6(3), 57-63
DOI: 10.12691/ijp-6-3-2
Open AccessArticle

Exchange Interaction of Quantum Entities as Interaction of Spin Vortices Created by the Quantum Entities in the Physical Vacuum

Liudmila B. Boldyreva1,

1State University of Management, Moscow 109542, Russia

Pub. Date: May 04, 2018

Cite this paper:
Liudmila B. Boldyreva. Exchange Interaction of Quantum Entities as Interaction of Spin Vortices Created by the Quantum Entities in the Physical Vacuum. International Journal of Physics. 2018; 6(3):57-63. doi: 10.12691/ijp-6-3-2

Abstract

The aim of this paper is to show that there is a physical process that underlies the exchange interaction of quantum entities. To this end the features of exchange interaction of quantum entities in the following physical phenomena are discussed: the creation of Cooper pairs in superconductors and superfluids, the covalent (molecular) bond, the interaction of light beams. The explanation of the exchange interaction is based on the concept of quantum mechanics according to which the quantum entity that is a singularity in electric and/or magnetic fields produces in the physical vacuum a pair of oppositely charged virtual particles having precessing spin, that is being essentially a spin vortex in the physical vacuum. The analysis of the above mentioned phenomena allows one to suppose that the exchange interaction of quantum entities in these phenomena may be due to interaction of spin vortices created by these quantum entities in the physical vacuum. It is shown also that the interaction of these vortices may be an electric dipole-dipole interaction. The equations describing the electric dipole-dipole interaction of spin vortices are derived in this work. A possibility of influence of the dipole-dipole interaction of spin vortices created by quantum entities that constitute the medium on viscosity of the medium, that is, on its superconductive and superfluid properties is considered.

Keywords:
exchange interaction spin vortex virtual particles pair electric dipole moment of spin vortex spin frequency of wave function

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References:

[1]  Griffiths, D, Introduction to Quantum Mechanics (2nd ed.), , 207-210, 2004.
 
[2]  Bardeen, J.; Cooper, L.N.; Schrieffer, J.R, “Theory of Superconductivity”, Phys Rev, 108 (5), 1175-1204, 1957.
 
[3]  Salomaa, M.M.; Volovik, G.E, “Quantized vortices in superfluid 3He”, Rev Mod Phy, 59 (3 Part I), 533-613, 1987.
 
[4]  Cammarata. A.; Rondinelli, J.M, “Covalent dependence of octahedral rotations in orthorhombic perovskite oxides”, J Chem Phys, 141 (11), 114704, 2014.
 
[5]  Mo, L.; Xiong, W.H.P.; Pernice, C.; Baehr-Jones, T.; Hochberg, V.; Tang, H.X, “Harnessing optical forces in integrated photonic circuits”, Nature, 456, 480-484, 2008.
 
[6]  Wichmann, E.H, Quantum Physics. Berkeley physics course, v. IV. McGraw-Hill Book company, 1971.
 
[7]  Myakishev, G.Ya, “Virtual Particles”. In book Physics of microworld. Little encyclopedia. 132-133, Soviet Encyclopedia Publishing House, Moscow, 1988 (In Russian).
 
[8]  Milonni, P.W, The quantum vacuum. Academic Press, Inc. Harcourt Brace & Company, Publishers, 1994.
 
[9]  Baars, J.W.M.; Lucas, R.; Mangum, J.G.; Lopez-Perez J.A, “Near-Field Radio Holography of Large Reflector Antennas”, IEEE Antennas and Propagation Magazine, 49 (5), 1-13, 2007.
 
[10]  Boldyreva, L.B, “Quantum correlations–Spin supercurrents”, International Journal of Quantum Information, 12 (1), 1450007 (13 pages), 2014.
 
[11]  Boldyreva, L.B, “The Spin Magnetic Moment of Electron as a Photon Property”, International Journal of Physics, 5 (3), 67-32, 2017.
 
[12]  Boldyreva, L.B, “The Theory of Virtual Particles as an Alternative to Special Relativity”, International Journal of Physics, 5 (4), 141-146. 2017.
 
[13]  Mineev, V.P, “Superfluid 3He: introduction to the subject”, Sov Physics Uspekhi, 26 (2), 160-175, 1983.
 
[14]  Abragam, A.; Goldman, M, Nuclear magnetism: order & disorder. V.2 Clarendon Press Oxford, 1983.
 
[15]  Pokazaniev, V.G.; Skrotskii, G.V, “Pseudomagnetism”, Uspekhi Fizicheskikh Nauk, 129 (Issue 4) 615-644, 1979 (in Russian).
 
[16]  Stephenson, A, “On the Curie points and Weiss molecular field coefficients of ferrimagnetic spinels”, Physics Letters A, 43 (Issue 3), 295-296, 1973.
 
[17]  Richardsоn, F; Riehl, J, “Circularly polarized luminescence spectroscopy”, Chem Revs, 77, 773, 1977.
 
[18]  Borovic-Romanov, A.S.; Bunkov, Yu.M.; Dmitriev, V.V.; Mukharskii, Yu.M.; Sergatskov, D.A, “Investigation of Spin Supercurrents in 3He-B”, Phys Rev Lett 62 (14), 1631, 1989.
 
[19]  Klyshko, D.N, “Quantum optics: quantum, classical, and metaphysical aspect”, Physics Uspekhi 37, 1097-1122, 1994.
 
[20]  Eisenschitz, R.; London, F, “Über das Verhältnis der van der Waalsschen Kräfte zu den homöopolaren Bindungskräften”, Zeitschrift für Physik, 60 (7-8), 491-527, 1930.
 
[21]  Purcell, E.М, Electricity and Magnetism. Berkeley physics course, vol. 2, McGraw-Hill Book company, 1965.
 
[22]  Kaufmann, W, “Die elektromagnetische Masse des Elektrons“, Physikalische Zeitschrift, 4 (1b), 54-56, 1902.
 
[23]  Thomas, L.T, “The Kinematics of an Electron with an Axis”, Philosophical Magazine, 3 (1), 1-22, 1927.