Mathias Wagner scite author profile

We present results for the equation of state in (2+1)-flavor QCD using the highly improved staggered quark action and lattices with temporal extent Nτ = 6, 8, 10, and 12. We show that these data can be reliably extrapolated to the continuum limit and obtain a number of thermodynamic quantities and the speed of sound in the temperature range (130-400) MeV. We compare our results with previous calculations, and provide an analytic parameterization of the pressure, from which other thermodynamic quantities can be calculated, for use in phenomenology. We show that the energy density in the crossover region, 145 MeV ≤ T ≤ 163 MeV, defined by the chiral transition, is c = (0.18 − 0.5) GeV/fm 3 , i.e., (1.2 − 3.1) nuclear . At high temperatures, we compare our results with resummed and dimensionally reduced perturbation theory calculations. As a byproduct of our analyses, we obtain the values of the scale parameters r0 from the static quark potential and w0 from the gradient flow.

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QCD equation of state to O(μB6) from lattice QCD

Bazavov

et al. 2017

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We calculated the QCD equation of state using Taylor expansions that include contributions from up to sixth order in the baryon, strangeness and electric charge chemical potentials. Calculations have been performed with the Highly Improved Staggered Quark action in the temperature range T ∈ [135 MeV, 330 MeV] using up to four different sets of lattice cut-offs corresponding to lattices of size N 3 σ × Nτ with aspect ratio Nσ/Nτ = 4 and Nτ = 6 − 16. The strange quark mass is tuned to its physical value and we use two strange to light quark mass ratios ms/m l = 20 and 27, which in the continuum limit correspond to a pion mass of about 160 MeV and 140 MeV respectively. Sixth-order results for Taylor expansion coefficients are used to estimate truncation errors of the fourth-order expansion. We show that truncation errors are small for baryon chemical potentials less then twice the temperature (µB ≤ 2T ). The fourth-order equation of state thus is suitable for the modeling of dense matter created in heavy ion collisions with center-of-mass energies down to √ sNN ∼ 12 GeV. We provide a parametrization of basic thermodynamic quantities that can be readily used in hydrodynamic simulation codes. The results on up to sixth order expansion coefficients of bulk thermodynamics are used for the calculation of lines of constant pressure, energy and entropy densities in the T -µB plane and are compared with the crossover line for the QCD chiral transition as well as with experimental results on freeze-out parameters in heavy ion collisions. These coefficients also provide estimates for the location of a possible critical point. We argue that results on sixth order expansion coefficients disfavor the existence of a critical point in the QCD phase diagram for µB/T ≤ 2 and T /Tc(µB = 0) > 0.9.

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Publisher’s Note:J/ψProduction versus Centrality, Transverse Momentum, and Rapidity inAu+AuCollisions atsN
Adare¹,
Afanasiev²,
Aidala³
et al. 2007
Phys. Rev. Lett.
227
46
357
1
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Freeze-Out Conditions in Heavy Ion Collisions from QCD Thermodynamics

et al. 2012

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We present a determination of freeze-out conditions in heavy ion collisions based on ratios of cumulants of net electric charge fluctuations. These ratios can reliably be calculated in lattice QCD for a wide range of chemical potential values by using a next-to-leading order Taylor series expansion around the limit of vanishing baryon, electric charge and strangeness chemical potentials. From a computation of up to fourth order cumulants and charge correlations we first determine the strangeness and electric charge chemical potentials that characterize freeze-out conditions in a heavy ion collision and confirm that in the temperature range 150 MeV ≤ T ≤ 170 MeV the hadron resonance gas model provides good approximations for these parameters that agree with QCD calculations on the 5%-15% level. We then show that a comparison of lattice QCD results for ratios of up to third order cumulants of electric charge fluctuations with experimental results allows us to extract the freeze-out baryon chemical potential and the freeze-out temperature.

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Mathias Wagner

Formation of dense partonic matter in relativistic nucleus–nucleus collisions at RHIC: Experimental evaluation by the PHENIX Collaboration

Equation of state in (2+1)-flavor QCD

QCD equation of state to O(μB6) from lattice QCD

Publisher’s Note:J/ψProduction versus Centrality, Transverse Momentum, and Rapidity inAu+AuCollisions atsN
Adare¹,
Afanasiev²,
Aidala³
et al. 2007
Phys. Rev. Lett.
227
46
357
1
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Freeze-Out Conditions in Heavy Ion Collisions from QCD Thermodynamics

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Mathias Wagner

Formation of dense partonic matter in relativistic nucleus–nucleus collisions at RHIC: Experimental evaluation by the PHENIX Collaboration

Equation of state in (2+1)-flavor QCD

QCD equation of state to O(μB6) from lattice QCD

Publisher’s Note:J/ψProduction versus Centrality, Transverse Momentum, and Rapidity inAu+AuCollisions atsNAdare1, Afanasiev2, Aidala3 et al. 2007Phys. Rev. Lett.227463571View full textAdd to dashboardCite

Freeze-Out Conditions in Heavy Ion Collisions from QCD Thermodynamics

Contact Info

Product

Resources

About

Publisher’s Note:J/ψProduction versus Centrality, Transverse Momentum, and Rapidity inAu+AuCollisions atsN
Adare¹,
Afanasiev²,
Aidala³
et al. 2007
Phys. Rev. Lett.
227
46
357
1
View full text Add to dashboard Cite