Chemical freeze-out temperature in the hydrodynamical description of Au+ Au collisions at
P Huovinen - The European Physical Journal A, 2008 - Springer
P Huovinen
The European Physical Journal A, 2008•SpringerWe study the effect of separate chemical and kinetic freeze-outs to the ideal hydrodynamical
flow in Au+ Au collisions at RHIC (^ S NN= 200 GeV energy). Unlike earlier studies we
explore how these effects can be counteracted by changes in the initial state of the
hydrodynamical evolution. We conclude that the reproduction of pion, proton and antiproton
yields necessitates a chemical freeze-out temperature of T≈ 150MeV instead of T= 160–
170 MeV motivated by thermal models. Contrary to previous reports, this lower temperature …
flow in Au+ Au collisions at RHIC (^ S NN= 200 GeV energy). Unlike earlier studies we
explore how these effects can be counteracted by changes in the initial state of the
hydrodynamical evolution. We conclude that the reproduction of pion, proton and antiproton
yields necessitates a chemical freeze-out temperature of T≈ 150MeV instead of T= 160–
170 MeV motivated by thermal models. Contrary to previous reports, this lower temperature …
Abstract
We study the effect of separate chemical and kinetic freeze-outs to the ideal hydrodynamical flow in Au + Au collisions at RHIC ( energy). Unlike earlier studies we explore how these effects can be counteracted by changes in the initial state of the hydrodynamical evolution. We conclude that the reproduction of pion, proton and antiproton yields necessitates a chemical freeze-out temperature of T ≈ 150MeV instead of T = 160–170 MeV motivated by thermal models. Contrary to previous reports, this lower temperature makes it possible to reproduce the p T spectra of hadrons if one assumes very small initial time, τ 0 = 0.2 fm/c. However, the p T differential elliptic flow, v 2(p T) remains badly reproduced. This points to the need to include dissipative effects (viscosity) or some other refinement to the model.
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