Non-extensive NJL model study of QCD phase structure with chiral imbalance and strong magnetic fields

Abstract

Based on the two-flavor NJL model with Tsallis non-extensive statistics, this work explores the QCD phase structure and thermodynamic properties under strong magnetic fields and chiral imbalance. The Tsallis parameter q captures non-equilibrium effects relevant to heavy-ion collisions. Key findings reveal that the critical temperature Tc decreases with increasing q, indicating that non-equilibrium conditions promote chiral symmetry restoration at lower temperatures. The chiral chemical potential μ5 significantly alters the magnetic response, with a transition from magnetic catalysis to inverse magnetic catalysis under certain conditions. For q > 1, non-monotonic behavior of Tc with magnetic field eB emerges. Pressure becomes anisotropic under strong eB, and the speed of sound exhibits a dip near Tc, shifting to lower temperatures with larger q. These results highlight how non-extensive statistics, chiral imbalance, and magnetic fields collectively influence the QCD phase diagram and thermodynamic observables, offering insights for interpreting heavy-ion collision data.