Current quark mass and nonzero-ness of chiral condensates in thermal Nambu-Jona-Lasinio model

Abstract

The effect that the current quark mass M0 may result in nonzero-ness of chiral condensates is systematically reexamined and analyzed in a two-flavor Nambu-Jona-Lasinio model simulating Quantum Chromodynamics (QCD) at temperature T and finite quark chemical potential μ without and with electrical neutrality (EN) condition and at any T and μ without EN condition. By means of a quantitative investigation of the order parameter m, it is shown that a nonzero M0 is bound to lead to nonzero quark-antiquark condensates throughout chiral phase transitions , no matter whether the order parameter m varies discontinuously or continuously. In fact, a complete disappearance of the quark-antiquark condensates are proven to demand the non-physical and unrealistic conditions μ \,≥ or \, 2+M02 if T=0 and finite, or T ∞ if μ<2+M02, where is the 3D momentum cut of the loop integrals. Theoretically these results show that when M0 is included, we never have a complete restoration of dynamical (spontaneous) chiral symmetry breaking, including after a first order chiral phase transition at low T and high μ. In physical reality, it is the nonzero-ness of the quark-antiquark condensates that leads to the appearance of a critical end point in the first order phase transition line and the crossover behavior at high T and/or high μ cases, rather than a possible tricritical point and a second order phase transition line. They also provide a basic reason for that one must consider the interplay between the chiral and diquark condensates in the research on color superconductor at zero T and high μ case. The research shows that how a source term of the Lagrangian (at present i.e. the current quark mass term) can greatly affect dynamical behavior of a physical system.