Schwinger Pair Production in QCD from Flavor-Dependent Contact Interaction Model of Quarks

Abstract

We study the Schwinger mechanism in QCD i.e., the quark-antiquark pair production rate in the presence of pure electric field strength eE, for a higher number of colors Nc and flavors Nf. In this context, our unified formalism is based on the Schwinger-Dyson equations, flavor-dependent symmetry preserving vector-vector contact interaction model of quarks, and an optimal time regularization scheme. For fixed Nc=3 and Nf=2, the dynamically quark mass decreases as we increase eE and near at and above the pseudo-critical electric field eEc, the chiral symmetry is restored and quarks becomes unconfined. The pair production rate becomes stable and grows quickly above eEc. For fixed Nc=3 and upon increasing Nf the dynamical mass suppresses and as a result, the eEc reduces to its smaller values, the pair production rate tends to initiates and grows quickly for smaller values of eEc. In contrast, for fixed Nf=2 and upon increasing Nc, the dynamical chiral symmetry is restored for larger and larger values of eEc and at Nc≥4, the transition changes from smooth cross-over to the first order at some critical endpoint (Nc,p, eEc,p). Consequently, the quark-antiquark production rate needs higher values of eEc for the stable and quick growth as we increase Nc. Our findings are satisfactory and in agreement with already predicted results for pair production rate (for fixed Nc=3 and Nf=2) by other reliable effective models of QCD.