Abstract
Nambu-Jona-Lasinio-type models are often employed as low-energy models for the theory of the strong interaction to analyze its phase structure at finite temperature and quark chemical potential. In particular at low temperature and large chemical potential, where the application of fully first-principles approaches is currently difficult at best, this class of models still plays a prominent role to guide our understanding of the dynamics of dense strong-interaction matter. In this work, we consider a Fierz-complete version of the Nambu-Jona-Lasinio model with two massless quark flavors and study its renormalization group flow and fixed-point structure at leading order of the derivative expansion of the effective action. Sum rules for the various four-quark couplings then allow us to monitor the strength of the breaking of the axial $U_{\rm A}(1)$ symmetry close to and above the phase boundary. We find that the dynamics in the ten-dimensional Fierz-complete space of four-quark couplings can only be reduced to a one-dimensional space associated with the scalar-pseudoscalar coupling in the strict large-$N_{\rm c}$ limit. Still, the interacting fixed point associated with this one-dimensional subspace appears to govern the dynamics at small quark chemical potential even beyond the large-$N_{\rm c}$ limit. At large chemical potential, corrections beyond the large-$N_{\rm c}$ limit become important and the dynamics is dominated by diquarks, favoring the formation of a chirally symmetric diquark condensate. In this regime, our study suggests that the phase boundary is shifted to higher temperatures when a Fierz-complete set of four-quark interactions is considered.
Highlights
Despite the tremendous progress that has been made in the development of fully first-principles approaches to the theory of the strong interaction in recent years, low-energy models of the theory of the strong interaction (QCD) are still considered very valuable for a variety of reasons
In the present work, which is a sequel of Ref. [10], we extend our analysis to an NJL model with massless quark flavors coming in Nc colors and two flavors to gain a better understanding of how Fierzincomplete approximations of QCD low-energy models affect the predictions for the phase structure at finite temperature and density
We have used renormalization group (RG) flow equations of fourquark couplings to analyze the phase structure of an NJLtype model with two quark flavors coming in Nc colors at leading order of the derivative expansion of the effective action
Summary
Despite the tremendous progress that has been made in the development of fully first-principles approaches to the theory of the strong interaction in recent years, low-energy models of the theory of the strong interaction (QCD) are still considered very valuable for a variety of reasons. We shall consider a purely fermionic formulation of the NJL model with massless quarks coming in two flavors and Nc colors, aiming at an analysis of the effect of Fierz-incomplete approximations on the phase structure at finite temperature and density in QCD low-energy model studies. The two sum rules imply that a Fierz-complete basis of pointlike four-quark interactions in case of a theory invariant under SUðNcÞ ⊗ SULð2Þ ⊗ SURð2Þ ⊗ UVð1Þ ⊗ UAð1Þ transformations is composed of eight channels.
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