Confinement and the Global SU(3) Color Symmetry

Abstract

The global SU(3) color symmetry and its physical consequences are discussed. The N\"other current is actually governed by the conserved matter current of color charges if the color field generated by this charge is properly polarized. The color field strength of a charge can have a uniform part due to the nontrivial QCD vacuum field and the nonzero gluon condensate, which implies that the self-energy of a system with a net color charge is infinite and thereby cannot exist as a free state. This is precisely what the color confinement means. Accordingly, the Cornell type potential with the feature of the Casimir scaling is derived for a color singlet system composed of a static color charge and an anti-charge. The uniform color field also implies that a hadron has a minimal size and a minimal energy. Furthermore, the global SU(3) color symmetry requires that the minimal irreducible color singlet systems can only be qq, qqq, gg, ggg, qqg, qqqg and qqqg, etc., as such a multi-quark systems can only exist as a molecular configurations if there are no other binding mechanisms.