Quark confinement in presence of both chromoelectric and chromomagnetic fields and the structure of spacetime

Abstract

The strong interaction between quarks inside hadrons in curved spacetime is investigated in the presence of a new non-abelian gauge potential based on the SU(3) group. This potential presented both chromo-electric and chromo-magnetic fields, including a magnetic monopole-like term, together with a radial non-Abelian Coulomb-like component. A spacetime metric induced by the presence of a Yang-Mills field is derived by solving Einstein's equations in the specific limit where the SU(3) gauge symmetry is reduced to an embedded SU(2) subgroup, accompanied by a dynamical U(1) monopole sector. It is explicitly shown that the Schwarzschild radius of the strong interaction between quarks within hadrons corresponds approximately to the size of these latter and that the corresponding, for both quarks and gluons, wave function presents a discontinuity at Schwarzschild surface. The obtained results allow us to interpret the confinement of quarks as a geometric property of spacetime, emerging naturally from its structure without introducing any confinement potential. Moreover, the energy spectra of quarks in presence of chromo-electric and chromo-magnetic fields reproduce the mass of hadrons with a very good accuracy compared to the experimental data, and the presence of the residual non-abelian term correction enhance our numerical results.