Quantum Gravity and String Theory


Higgs Like Fluctuation at 240 GeV Possible Evidence for Sphere Theory’s Cuboctahedron Structure of Hubble Sphere Universe

Authors: Michael John Sarnowski

This paper proposes that the Atlas Higgs-Like fluctuation at 240 GeV, with 3.6 sigma probability, may be possible evidence for Sphere Theory’s Cuboctahedron Structure of Hubble Sphere Universe. Philip Gibbs highlights a prediction of Tony Smith’s prediction for a mass at 240 GeV. Tommaso Dorigo, writes an article about it on Science 2.0 and offers a possible wager. Due to the propagation of light, gravity, charge, magnetism etc., and their quantized values, it has been hypothesized that, the universe should be filled with some type of almost homogeneous structure. It was shown in “Evidence for Granular Spacetime”( 1) that charge and gravity could be modeled by a sphere with a Compton wavelength radius of the neutron. If the neutron Compton wavelength is important to the propagation of charge and gravity then it is proposed that it also must be connected to some structure of the volume in which these forces are transmitted. “Underlying Cuboctahedron Packing of Planck Spinning Spheres Structure of the Hubble Universe” establishes a strong correlation, on multiple levels, between underlying packing of Planck Spinning Spheres structure of the Hubble Universe correlation with higgs mass, W boson, Z boson, bottom Quark and top Quark and a cuboctahedron –Vector Equilibrium structure using the mass of the neutron and the combining of the layers of a cuboctahedron packing of spheres. The layers of a cuboctahedron follow a consistent progression for the quantity of spheres that can be packed in a layer. The masses of the w boson, z boson, bottom quark, top quark and the Higgs can be directly correlated to the first few layers of a cuboctahedron structure, and in a mirror manner described in this paper. This paper now shows that the Higgs-Like fluctuation at 240 GeV also follows the cuboctahedron progression for the quantity of spheres that can be packed in a layer.

Comments: 6 Pages.

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Submission history

[v1] 2017-07-28 08:01:57

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