Abstract
We show that the nonlocal two-flavor Nambu--Jona-Lasinio model predicts the enhancement of both chiral and axial symmetry breaking as the chiral imbalance of hot QCD matter, regulated by a chiral chemical potential $\mu_5$, increases. The two crossovers are reasonably close to each other in the range of $\mu_5$ examined here and the pseudocritical temperatures rise with $\mu_5$. The curvatures of the chiral and axial crossovers for the chiral quark chemical potential approximately coincide and give $\kappa_5 \simeq - 0.011$. We point out that the presence of $\mu_5$ in thermodynamic equilibrium is inconsistent with the fact that the chiral charge is not a Noether-conserved quantity for massive fermions. The chiral chemical potential should not, therefore, be considered as a true chemical potential that sets a thermodynamically stable environment in the massive theory, but rather than as a new coupling that may require a renormalization in the ultraviolet domain. The divergence of an unrenormalized chiral density, \corr{coming from zero-point fermionic fluctuations,} is a consequence of this property. We propose a solution to this problem via a renormalization procedure.
Highlights
The chirality plays an important role in the fundamental theory of strong interactions of quarks and gluons described by QCD
We show that the nonlocal two-flavor Nambu–Jona-Lasinio model predicts the enhancement of both chiral and axial symmetry breaking as the chiral imbalance of hot QCD matter, regulated by a chiral chemical potential μ5, increases
We report on the calculation of Tc versus μ5, confirming the previous findings that Tc increases with the chiral chemical potential at least as long as μ5 is smaller than the typical ultraviolet scale of the model
Summary
The chirality plays an important role in the fundamental theory of strong interactions of quarks and gluons described by QCD. As a consequence of the Noether theorem, the chiral charge is a conserved quantity at the level of classical equations of motion. In the quantum version of QCD, the chirality is no longer a conserved number because quantum fluctuations break the chiral symmetry spontaneously.
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