Chiral crossover in QCD at zero and non-zero chemical potentials

Using numerical simulations of lattice QCD with physical quark masses, we reveal the influence of magnetic-field background on chiral and deconfinement crossovers in finite-temperature QCD at low baryonic density. In the absence of thermodynamic singularity, we identify these transitions with inflection points of the approximate order parameters: normalized light-quark condensate and renormalized Polyakov loop, respectively. We show that the quadratic curvature of the chiral transition temperature in the "temperature-chemical potential" plane depends rather weakly on the strength of the background magnetic field. At weak magnetic fields, the thermal width of the chiral crossover gets narrower as the density of the baryon matter increases, possibly indicating a proximity to a real thermodynamic phase transition. Remarkably, the curvature of the chiral thermal width flips its sign at eB fl 0.6 GeV 2 , so that above the flipping point B > B fl , the chiral width gets wider as the baryon density increases. Approximately at the same strength of magnetic field, the chiral and deconfining crossovers merge together at T ≈ 140 MeV. The phase diagram in the parameter space "temperature-chemical potential-magnetic field" is outlined, and single-quark entropy and single-quark magnetization are explored. The curvature of the chiral thermal width allows us to estimate an approximate position of the chiral critical endpoint at zero magnetic field: (T CEP c , µ CEP B ) = (100(25) MeV, 800(140) MeV).

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“…In the zero-field limit, our data converge well to the known result T ch c = 156.5(1.5) MeV of Ref. [4], shown by the red square in Fig. 5(a).…”

Section: Chiral Transition Temperature and Its Curvaturesupporting

confidence: 90%

Finite-density QCD transition in a magnetic background field

et al. 2019

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“…We find T (χ2) c = 153 MeV, which is only slightly lower than the value from the inflection point of the subtracted condensate determined in the previous section to 156 MeV. Note again that there is no unique definition of the critical temperature due to the crossover nature of the transition and both values are in agreement with lattice QCD [6,7,10,11,89].…”

Section: B Quark Number Fluctuationssupporting

confidence: 70%

“…At zero chemical potential, there is firm evidence from lattice QCD for an analytic crossover from a low-temperature phase characterized by chiral symmetry breaking to a high-temperature (partially) chirally restored phase [4][5][6][7][8][9]. The corresponding pseudocritical temperature has been localized at T c ≈ 156 MeV within a definition-dependent range of several MeV [6,7,10,11]. However, the situation is much less clear at (real) chemical potential, where lattice calculations are hampered by the notorious fermion sign problem.…”

Section: Introductionmentioning

confidence: 99%

Baryon number fluctuations in the QCD phase diagram from Dyson-Schwinger equations

et al. 2019

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We present results for fluctuations of the baryon number for QCD at non-zero temperature and chemical potential. These are extracted from solutions to a coupled set of truncated Dyson-Schwinger equations for the quark and gluon propagators of Landau gauge QCD with N f = 2 + 1 quark flavors, that has been studied previously. We discuss the changes of fluctuations and ratios thereof up to fourth order for several temperatures and baryon chemical potential up to and beyond the critical end point. In the context of preliminary STAR data for the skewness and kurtosis ratios, the results are compatible with the scenario of a critical end point at large chemical potential and slightly offset from the freeze-out line. We also discuss the caveats involved in this comparison.

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“…Figure 1 summarizes the current status of the studies. At the zero baryonic density, the transition from QGP to hadronic matter is a smooth-crossover at T = 150 − 160 MeV [5][6][7][8][9], see dashed-line in the figure. These results are extracted from the state of the art Lattice gauge theory calculations.…”

Section: Introductionmentioning

confidence: 99%

“…[12]. The dashed-line near µ B = 0 indicates the crossover transition from the Quark-Gluon-Plasma to Hadron Gas [5][6][7][8][9]. The solid-line and the square show the expected 1st-order phase boundary and its end point: critical point.…”

Section: Introductionmentioning

confidence: 99%

A Study of the Properties of the QCD Phase Diagram in High-Energy Nuclear Collisions

Luo

Shi

et al. 2020

Particles

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With the aim of understanding the phase structure of nuclear matter created in high-energy nuclear collisions at finite baryon density, a beam energy scan program has been carried out at Relativistic Heavy Ion Collider (RHIC). In this mini-review, most recent experimental results on collectivity, criticality and heavy flavor productions will be discussed. The goal here is to establish the connection between current available data and future heavy-ion collision experiments in a high baryon density region.Particles 2020, xx, 5 0 -5% 60 -80% 0 -5% Au+Au at RHIC Pb+Pb at LHC A. Andronic, et al., NPA834, 237(10) J. Cleymans, et al., PRC73, 34905(06) Lattice fits

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Chiral crossover in QCD at zero and non-zero chemical potentials

Cited by 507 publications

References 47 publications

Finite-density QCD transition in a magnetic background field

Finite-density QCD transition in a magnetic background field

Baryon number fluctuations in the QCD phase diagram from Dyson-Schwinger equations

A Study of the Properties of the QCD Phase Diagram in High-Energy Nuclear Collisions

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