Abstract
Previously the 5D homogeneous space-time metric was introduced with explicitly given projection operators in matrix form which map the 5D space-time manifold into a Lorentzian space-time. Based on this projection model, vector field and spinor solutions are found to be expressible in terms of SU(2)xL and SU(3)xL, where L is the 4D Lorentz space-time group. The spinor solutions give the SU(2) leptonic states arising from space-time projection, whereas the SU(3) representation arises from conformal projection and gives the quarks, and due to gauge requirement leads to mesons and baryons. This process of mapping the 5D space-time manifold into the 4D space-time is at the basis of an analysis of the recent CERN experimental results, the presence of neutrino oscillations and the observed 125 GeV resonance in the p-p collisions, respectively. In fact, it is found that the spinor solution contains an oscillating phase, and the 125 GeV resonance is shown to be predictable, thereby 1) eliminating the need to introduce a Higgs vacuum, and 2) can be shown possibly to be an indicator for a missing heavy baryon octet.
Highlights
There was some excitement within the physics community related to results of two fundamental experimental findings
The spinor solutions give the SU(2) leptonic states arising from space-time projection, whereas the SU(3) representation arises from conformal projection and gives the quarks, and due to gauge requirement leads to mesons and baryons
We proposed a 5D homogeneous space-time domain [9], and showed that we can derive the quarks of the standard model by imposing a projection action
Summary
There was some excitement within the physics community related to results of two fundamental experimental findings. By far the more publicized is the finding of a 125 GeV two photon emission obtained from the p-p collision experiment done by the CERN Large Hadron Collider [1,2] and the Tevatron [3] It is billed as an indication of the existence of the Higgs Boson, which was advanced some half a century ago by Higgs [4] for giving the quarks of Gell-Mann’s standard model [5] their basic masses. The second experimental finding is the oscillation of the neutrino states [6,7,8], making the three leptonic neutrinos able to evolve into each other on their propagation through space-time It is these two interesting results that we like to discuss in this paper.
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