Thermal-FIST: A package for heavy-ion collisions and hadronic equation of state

Vovchenko, Volodymyr; Stoecker, Horst

doi:10.1016/j.cpc.2019.06.024

Cited by 93 publications

(58 citation statements)

References 96 publications

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“…We see that for Pb-Pb collisions the freeze-out temperature is in 152-156 MeV range and close to the chemical freezeout temperature T chem = 156.5 ± 1.5 MeV obtained by the statistical model fitted to light and multi-strange hadrons in the most central collisions [2]. Studies of centrality dependence of thermal model parameters also find weak temperature dependence, but the temperature is higher than extracted in out fits [39][40][41]. We note that in our model we use only π, K, p spectra and do not introduce baryon chemical potential, canonical suppression or strangeness undersaturation effects.…”

supporting

confidence: 78%

Temperature and fluid velocity on the freeze-out surface from π , K , and p spectra in pp ,
Mazeliauskas
¹
,
Vislavicius
²

2020
Phys. Rev. C

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We present a new approach to take into account resonance decays in the blast-wave model fits of identified hadron spectra. Thanks to pre-calculated decayed particle spectra, we are able to extract, in a matter of seconds, the multiplicity dependence of the single freeze-out temperature T fo , average fluid velocity βT , velocity exponent n, and the volume dV /dy of an expanding fireball. In contrast to blast-wave fits without resonance feed-down, our approach results in a freeze-out temperature of T fo ∼ 155 MeV, which has only weak dependence on multiplicity and collision system. Finally, we discuss the case of separate chemical and kinetic freeze-outs.

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supporting

confidence: 78%

Temperature and fluid velocity on the freeze-out surface from π , K , and p spectra in pp ,
Mazeliauskas
¹
,
Vislavicius
²

2020
Phys. Rev. C

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“…Using the implementation of the hadron resonance gas of Ref. [39] we find (N/N ch ) TF = 1.09. In the following we use N/N ch = 1.115 ± 0.03, i.e., we take the average of the two results as central value and the difference as a measure of the uncertainty.…”

Section: Comparisons To Statistical Modelsmentioning

confidence: 93%

Entropy production in pp and Pb-Pb collisions at energies available at the CERN Large Hadron Collider

2019

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We use experimentally measured identified particle spectra and Hanbury Brown-Twiss radii to determine the entropy per unit rapidity dS/dy produced in √ s = 7 TeV pp and √ s NN = 2.76 TeV Pb-Pb collisions. We find that dS/dy = 11 335 ± 1188 in 0%-10% Pb-Pb, dS/dy = 135.7 ± 17.9 in high-multiplicity pp, and dS/dy = 37.8 ± 3.7 in minimum bias pp collisions and compare the corresponding entropy per charged particle (dS/dy)/(dN ch /dy) to predictions of statistical models. Finally, we use the quantum chromodynamics kinetic theory pre-equilibrium and viscous hydrodynamics to model entropy production in the collision and reconstruct the average temperature profile at τ 0 ≈ 1 fm/c for high-multiplicity pp and Pb-Pb collisions.

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“…In this section the thermodynamical variables are calculated for each hadron species and for each investigated system. The results of the integrations defined by equations (12) With solid curves several theoretical models are shown, including lattice QCD calculations (Budapest -Wuppertal, with red [129] and HotQCD, with green [130]), a hadron resonance gas model (Thermal-FIST, with orange [131]), a Polyakov constituent quark-meson model (Kovács -Szép -Wolf, with blue [132]), and an effective field theory with hadronic-like spectral functions in the QGP until temperatures as high as (3)(4)T c (Biró -Jakovác, with brown [133]). In this latter approach the thermodynamic quantities can be calculated analytically.…”

Section: Thermodynamical Validation Within the Non-extensive Approachmentioning

confidence: 99%

“…The scaled pressure, P/T 4 and energy density, ε/T 4 of identified hadrons in pp, pA and AA collisions at various collision energies, in the function of the temperature T . The theoretical curves are taken from[129][130][131][132][133]. , EV, r = 0.15 fm Kovacs-Szep-Wolf (Polyakov loop) Biro-Jakovac (hadronic dof) Tsallis-thermometer…”

mentioning

confidence: 99%

Tsallis-thermometer: a QGP indicator for large and small collisional systems

Bíró¹,

Barnaföldi²,

Bı́ró³

2020

J. Phys. G: Nucl. Part. Phys.

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The transverse momentum distribution of identified hadrons from recent years are analyzed within the thermodynamically consistent formulation of nonextensive statistics. A wide range of center-of-mass energies and average event multiplicities are studied for various hadron species. We demonstrate that the average event multiplicity is a key variable in the study of high-energy collisions and a smooth transition in the description from small to large systems is possible. For this purpose the non-extensive statistical approach is more than appropriate. The validity of the non-extensive description is explored in multiple ways: such as the calculation of integrated yields per unit rapidity, the analysis of radial flow and the consistency check of the thermodynamical variables. The 'Tsallis-thermometer' is introduced as an indicator of quark-gluon plasma in small collisional systems.

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Thermal-FIST: A package for heavy-ion collisions and hadronic equation of state

Cited by 93 publications

References 96 publications

Temperature and fluid velocity on the freeze-out surface from π , K , and p spectra in pp ,
Mazeliauskas
¹
,
Vislavicius
²

2020
Phys. Rev. C

Temperature and fluid velocity on the freeze-out surface from π , K , and p spectra in pp ,
Mazeliauskas
¹
,
Vislavicius
²

2020
Phys. Rev. C

Entropy production in pp and Pb-Pb collisions at energies available at the CERN Large Hadron Collider

Tsallis-thermometer: a QGP indicator for large and small collisional systems

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Thermal-FIST: A package for heavy-ion collisions and hadronic equation of state

Cited by 93 publications

References 96 publications

Temperature and fluid velocity on the freeze-out surface from π , K , and p spectra in pp , Mazeliauskas1, Vislavicius2 2020Phys. Rev. C

Temperature and fluid velocity on the freeze-out surface from π , K , and p spectra in pp , Mazeliauskas1, Vislavicius2 2020Phys. Rev. C

Entropy production in pp and Pb-Pb collisions at energies available at the CERN Large Hadron Collider

Tsallis-thermometer: a QGP indicator for large and small collisional systems

Contact Info

Product

Resources

About

Temperature and fluid velocity on the freeze-out surface from π , K , and p spectra in pp ,
Mazeliauskas
¹
,
Vislavicius
²

2020
Phys. Rev. C

Temperature and fluid velocity on the freeze-out surface from π , K , and p spectra in pp ,
Mazeliauskas
¹
,
Vislavicius
²

2020
Phys. Rev. C