Subatomic Particle Structures and Unified Field Theory Based on Yangton and Yington Hypothetical Theory
American Journal of Modern Physics
Volume 4, Issue 4, July 2015, Pages: 189-195
Received: May 26, 2015;
Accepted: Jun. 7, 2015;
Published: Jun. 30, 2015
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Edward T. H. Wu, Solar Buster Corporation, Los Angeles, USA
A hypothetical theory of a Yangton and Yington circulating pair with an inter-attractive “Force of Creation” is proposed as the “Origin of Creation”. When this circulating pair travels in the space it is known as “Photon”. Otherwise, at still, it is known as “Wu’s Particles” also as “Still Photon”, which makes the basic building block of all matters. The structures of Quarks, Neutrinos, Higgs Boson particles, Electron, Positron, Proton, Neutron, and Dark Matters are proposed based on “Wu’s Particles”. Also, it is assumed that “Force of Creation” is the only fundamental force in the universe that could create and unify the Four Basic Forces. Gravitation is formed by the attractive force between two Higgs Boson particles with String Structures that are made of “Wu’s Particles” of the same circulation direction. Electromagnetism is however generated between two atoms both with single outer layer Electron that are attractive to each other while spinning in the same direction and repulsive in the opposite directions. Both the Weak Force between Neutron and Positron as well as the Strong Force between two Neutrons also between Proton and Neutron are proposed and interpreted based on “Wu’s Particles” and “Force of Creation”.
Edward T. H. Wu,
Subatomic Particle Structures and Unified Field Theory Based on Yangton and Yington Hypothetical Theory, American Journal of Modern Physics.
Vol. 4, No. 4,
2015, pp. 189-195.
Edward T. H. Wu, "Yangton and Yington – A Hypothetical Theory of Everything", Science Journal of Physics, Volume 2015, Article ID sjp-242, 6 Pages, 2015, doi: 10.7237/sjp/242
"Big-bang model". Encyclopedia Britannica. Retrieved 11 February 2015.
Braibant, S.; Giacomelli, G.; Spurio, M. (2009). Particles and Fundamental Interactions: An Introduction to Particle Physics. Springer. pp. 313–314. ISBN 978-94-007-2463-1.
Walter Greiner (2001). Quantum Mechanics: An Introduction. Springer. p. 29.ISBN 3-540- 67458-6.
"Quark (subatomic particle)". Encyclopedia Britannica. Retrieved 2008-06-29.
"Neutrino". Glossary for the Research Perspectives of the Max Planck Society. Max Planck Gesellschaft. Retrieved 2012-03-27.
P. A. M. Dirac. "The quantum theory of the Electron" (PDF).
Basdevant, J. L.; Rich, J.; M. Spiro (2005). Fundamentals in Nuclear Physics. Springer. p. 155. ISBN 0-387-01672-4.
Thomas, A.W.; Weise, W. (2001), The Structure of the Nucleon, Wiley-WCH, Berlin, ISBN 3-527-40297-7
Dark matter. CERN. Retrieved on 17 November 2014.
Davies, Paul (1986), The Forces of Nature, Cambridge Univ. Press 2nd ed.
Chandrasekhar, Subrahmanyan (2003). Newton's Principia for the common reader. Oxford: Oxford University Press. (pp.1–2).
Polchinski, Joseph (1998). String Theory, Cambridge University Press ISBN 0521672295.
Ravaioli, Fawwaz T. Ulaby, Eric Michielssen, Umberto (2010). Fundamentals of applied electromagnetics (6th ed.). Boston: Prentice Hall. p. 13. ISBN 978-0-13-213931-1.
J. Christman (2001). "The Weak Interaction" (PDF). Physnet. Michigan State University.
Chapter 4 NUCLEAR PROCESSES, THE STRONG FORCE, M. Ragheb 1/27/2012, University of Illinois
Reitz, John; Milford, Frederick; Christy, Robert (1992). Foundations of Electromagnetic Theory (4th Ed.). Addison Wesley. ISBN 0-201-52624-7.
Konya, J.; Nagy, N. M. (2012). Nuclear and Radiochemistry. Elsevier. pp. 74-75. ISBN 978-0-12-391487-3.