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From Black-Body Radiation to Gravity: Why Quarks are Magnetic Electrons and why Gluons are Massive Photons


Affiliations
1 Philips Research Labs, Eindhoven, Netherlands
 

In an historic perspective on the development of the Standard Model of particle physics it is shown how mathematically driven axioms have masked the merits of a physically comprehensible structural view. It is concluded that the difference between the two approaches can be traced back to two major issues. Whereas in the Standard Model the quark is a Dirac particle with a single real dipole moment, the quark in the structural model, in confinement with other quarks, is a Dirac particle with two real dipole moments. The second issue is the view that empty space does not exist, but that space is filled with a polarizable energetic fluid. It is shown how recognition of these two issues paves a road to reconcile particle physics with gravity, in which the quark can be seen as a magnetic electron and in which the gluon, as the strong force carrier, can be seen as a massive photon.

Keywords

Gluon, Strong Interaction, Weak Interaction, Topquark, Gravity, SU(2) and SU(3).
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  • From Black-Body Radiation to Gravity: Why Quarks are Magnetic Electrons and why Gluons are Massive Photons

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Authors

Engel Roza
Philips Research Labs, Eindhoven, Netherlands

Abstract


In an historic perspective on the development of the Standard Model of particle physics it is shown how mathematically driven axioms have masked the merits of a physically comprehensible structural view. It is concluded that the difference between the two approaches can be traced back to two major issues. Whereas in the Standard Model the quark is a Dirac particle with a single real dipole moment, the quark in the structural model, in confinement with other quarks, is a Dirac particle with two real dipole moments. The second issue is the view that empty space does not exist, but that space is filled with a polarizable energetic fluid. It is shown how recognition of these two issues paves a road to reconcile particle physics with gravity, in which the quark can be seen as a magnetic electron and in which the gluon, as the strong force carrier, can be seen as a massive photon.

Keywords


Gluon, Strong Interaction, Weak Interaction, Topquark, Gravity, SU(2) and SU(3).

References