Color-flavor dependence of the Nambu-Jona-Lasinio model and QCD phase diagram

Abstract

We study the dynamical chiral symmetry breaking/restoration for the various numbers of light quarks flavors Nf and colors Nc, using the Nambu-Jona-Lasinio (NJL) model of quarks, dressed with a color-flavor dependence of effective coupling. Initially, we set Nf = 2, and varying the number of colors Nc, we find that the dynamical chiral symmetry is broken when Nc exceeds to its critical value Ncc≈2.2. Secondly, we take Nc = 3, and varying Nf, we observed that the dynamical chiral symmetry is restored when Nf reaches to its critical value Ncf≈8. The strong interplay observed between Nc and Nf, i.e., Nc anti-screens the strong interactions by strengthening the dynamical mass and quark-antiquark condensate, while Nf screens the strong interaction by suppressing both the parameters. We further sketch the quantum chromodynamics (QCD) phase diagram at finite temperature T and quark chemical potential μ for various Nc and Nf. At finite T and μ, we observed that the critical number of colors Ncc enhances while the critical number of flavors Ncf suppresses as T and μ increases. Of course, the parameters T and μ produce the screening effect. Consequently, the critical temperature Tc, μc and co-ordinates of the critical endpoint (TEc,μEc) in the QCD phase diagram enhances as Nc increases while suppresses when Nf increases. Our findings agree with the Lattice QCD and Schwinger-Dyson equations predictions.