Collective flow and two-pion correlations from a relativistic
  hydrodynamic model with early chemical freeze out

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Abstract

We investigate the effect of early chemical freeze-out on radial flow, elliptic flow and HBT radii by using a fully three dimensional hydrodynamic model. When we take account of the early chemical freeze-out, the space-time evolution of temperature in the hadron phase is considerably different from the conventional model in which chemical equilibrium is always assumed. As a result, we find that radial and elliptic flows are suppressed and that the lifetime and the spatial size of the fluid are reduced. We analyze the p_t spectrum, the differential elliptic flow, and the HBT radii at the RHIC energy by using hydrodynamics with chemically non-equilibrium equation of state.

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Record: found
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Article: not found

Anisotropy as a signature of transverse collective flow

Jean-Yves Ollitrault (1992)

0 comments Cited 542 times – based on 0 reviews      Review now

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Record: found
Abstract: not found
Article: not found

Single-particle distribution in the hydrodynamic and statistical thermodynamic models of multiparticle production

Fred Cooper, Graham Frye (1974)

0 comments Cited 343 times – based on 0 reviews      Review now

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Is Open Access

Thermal phenomenology of hadrons from 200 AGeV S+S collisions

Josef Sollfrank, Ekkard Schnedermann, Ulrich Heinz (1993)

We develop a complete and consistent description for the hadron spectra from heavy ion collisions in terms of a few collective variables, in particular temperature, longitudinal and transverse flow. To achieve a meaningful comparison with presently available data, we also include the resonance decays into our picture. To disentangle the influences of transverse flow and resonance decays in the \(m_T\)-spectra, we analyse in detail the shape of the \(m_T\)-spectra.