The QCD phase structure at finite temperature and density

TL;DR

This paper uses the functional renormalisation group to explore the QCD phase diagram at finite temperature and density, identifying a critical endpoint and indications of inhomogeneous phases, aligning well with lattice results.

Contribution

It presents a systematic, dynamical approach to deriving the QCD phase diagram at finite density, including the location of the critical endpoint, from fundamental interactions.

Findings

Critical endpoint at (107 MeV, 635 MeV)

Curvature of phase boundary: 0.0142(2)

Indications of inhomogeneous regimes above the chiral transition

Abstract

We discuss the phase structure of QCD for $N_f=2$ and $N_f=2+1$ dynamical quark flavours at finite temperature and baryon chemical potential. It emerges dynamically from the underlying fundamental interactions between quarks and gluons in our work. To this end, starting from the perturbative high-energy regime, we systematically integrate-out quantum fluctuations towards low energies by using the functional renormalisation group. By dynamically hadronising the dominant interaction channels responsible for the formation of light mesons and quark condensates, we are able to extract the phase diagram for $\mu_B/T \lesssim 6$. We find a critical endpoint at $(T_\text{CEP},{\mu_B}_{\text{CEP}})=(107, 635)\,\text{MeV}$. The curvature of the phase boundary at small chemical potential is $\kappa=0.0142(2)$, computed from the renormalised light chiral condensate $\Delta_{l,R}$. Furthermore, we find indications for an inhomogeneous regime in the vicinity and above the chiral transition for $\mu_B\gtrsim 417$ MeV. Where applicable, our results are in very good agreement with the most recent lattice results. We also compare to results from other functional methods and phenomenological freeze-out data. This indicates that a consistent picture of the phase structure at finite baryon chemical potential is beginning to emerge. The systematic uncertainty of our results grows large in the density regime around the critical endpoint and we discuss necessary improvements of our current approximation towards a quantitatively precise determination of QCD phase diagram.