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New Deduced Results in Subatomic Physics

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DOI: 10.4236/jmp.2019.106047    73 Downloads   146 Views  
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The Standard Model of elementary particles, with its associated concept of a vacuum state of empty space, leads to strongly restricted results in subatomic physics. Examples are given by vanishing rest masses and an associated spinless state of the photon. In a revised quantum electrodynamic theory by the author, new results have been deduced which cannot be obtained from the Standard Model. These are due to a vacuum state populated by Zero Point Energy and a corresponding nonzero electric charge density. This leads to a screw-shaped photon configuration with rest mass, spin and possibilities of needle radiation, to a deduced value of the elementary charge of the electron, muon and tauon being close to its experimental value, to a deduced mass being nearly equal to 125 GeV of the Higgs particle detected at CERN, and to the discovery of large intrinsic charges of both polarities within the volume of a particle. In their turn, these charges give rise to effects of the same magnitude as that of the strong force, and can account for the binding energy of 8 MeV of the neutron and proton. This makes a unification possible of electrodynamics with the strong nuclear force.

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The author declares no conflicts of interest regarding the publication of this paper.

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Lehnert, B. (2019) New Deduced Results in Subatomic Physics. Journal of Modern Physics, 10, 663-672. doi: 10.4236/jmp.2019.106047.


[1] Lehnert, B. (2014) Revised Quantum Electrodynamics. In: Dvoeglazov, V.V., Ed., Contemporary Fundamental Physics, NovaScience Publishers, Inc., New York, 1-154.
[2] Lehnert, B. (2018) Impacts of Revised Quantum Electrodynamics on Fundamental Physics. Journal of Electromagnetic Analysis and Applications, 10, 106-118.
[3] Stratton, J.A. (1941) Electromagnetic Theory. 1st Edition, Ch. 1.10 and 1.11, McGraw-Hill Book Comp., Inc., New York and London.
[4] Quigg, C. (2008) The Coming Revolution in Particle Physics. Scientific American, 298, 46-53.
[5] Schiff, L.I. (1949) Quantum Mechanics. Ch. IV, Sec.13, McGraw-Hill Book Comp., Inc., New York, Toronto, London.
[6] Casimir, H.B.G. (1948) On the Attraction between Two Perfectly Conducting Plates. Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, 51, 793-795.
[7] Lamoreaux, S.K. (1997) Demonstration of the Casimir Force in the 0.6 to 6 µm Range. Physical Review Letters, 78, 5-8.
[8] Abbott, L. (1988) The Mystery of the Cosmological Constant. Scientific American, 258, 106-113.
[9] Lehnert, B. (2014) Some Consequences of Zero Point Energy. Journal of Electromagnetic Analysis and Applications, 6, 319-327.
[10] Lehnert, B. (2015) Zero Point Energy Effects on Quantum Electrodynamics. Journal of Modern Physics, 6, 448-452.
[11] Lehnert, B. (2016). On the Cosmical Zero Point Energy Density. Journal of Modern Physics, 7, 1112-1119.
[12] Lehnert, B. (2011) The Individual Photon in Two-Slit Experiments. International Review of Physics, 5, 15-18.
[13] Ryder, L.H. (1996) Quantum Field Theory. 2nd Edition, Cambridge University Press, Cambridge.
[14] Lehnert, B. (2010) Deduced Fundamental Properties of the Electron. International Review of Physics, 4, 1-6.
[15] Lehnert, B. and Scheffel, J. (2002) On the Minimum Elementary Charge of an Extended Electromagnetic Theory. Physica Scripta, 65, 200-207.
[16] Lehnert, B. and Höök, J. (2010) An Electron Model with Elementary Charge. Journal of Plasma Physics, 76, 419-428.
[17] Higgs, P.W. (1966) Spontaneous Symmetry Breakdown without Massless Bosons. Physical Review, 145, 1156-1168.
[18] ATLAS Collaboration. Aad, G., et al. (2012) Observation of a New Particle in the Search for the Standard Model Higgs Boson with the ATLAS Detector at the LHC. Physics Letters B, 716,1-29.
[19] CMS Collaboration. Chatrchyan, S., et al. (2012) Observation of a New Boson at a Mass of 125 GeV with the CMS Experiment at the LHS. Physics Letters B, 716, 30-61.
[20] Lehnert, B. (2013) Higgs-Like Particle Due to Revised Quantum Electrodynamics. Progress in Physics, 3, 31-32.
[21] Lehnert, B. (2014) Mass-Radius Relations of Z and Higgs-Like Bosons. Progress in Physics, 10, 5-7.
[22] Lehnert, B. (2015) Minimum Mass of a Composite Boson. Journal of Modern Physics, 6, 2074-2079.
[23] Lehnert, B. (2017) Intrinsic Particle Charges and the Strong Force. Journal of Modern Physics, 8, 1053-1066.
[24] Bethe, H.A. (1947) Elementary Nuclear Theory. Ch. 2, John Wiley and Sons, Inc., New York and Chapman and Hall, Ltd., London,118.
[25] Lehnert, B. (2018) Some Thoughts upon Long-Range Interaction and Entangled States. Journal of Electromagnetic Analysis and Applications, 10, 193-196.

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