Confining Quantum Chromodynamics Model for 3-Quark Baryons, New Mass Source, `Proton Spin Crisis' Solution and Idealized Quark-Lepton Mass Symmetry

Abstract

We discuss a model for the relativistic bound states of 3-quark baryons based on confining quantum chromoynamics (QCD) with general Yang-Mills symmetry. The model postulates that 3-quark states are formed by consecutive 2-body collisions. For a proton, d and u quarks get together first, and then they capture another u quark so that the d quark is at the core to form a stable proton state with intergral electric charge. The two u quarks form a quantum spheric shell and move in a confining potential C(r)= Q' r of the core d quark. The confining potential C(r) is a static solution of new `phase' fields satisfying the fourth-order equation based on general Yang-Mills symmetry. The two u quarks with the confining linear potentials C(r) in the spherical shell can produce an effective quark Hooke potential VqH(r)=Qr2 + Vo for the d quark at the core, where Q and Q' are not independent. The proton mass is assumed to be approximately given by E(d) + 2E(u), which can be obtained analytically from Dirac Hamiltonians involving VqH(r) and C(r) for d and two u quarks respectively. The model gives a reasonable understanding of roughly 120 baryon masses based on two different coupling constants and one free parameter Vo for sub-spectra specfied by JP. These results are roughly within 20\% in percent deviation, which appears to be independent of the assumption of color charges. The confining QCD model also gives the neutron-proton mass difference ≈ 0.6 MeV. We propose an experimental test of the proton structure.

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