English

Heavy Ion Collision evolution modeling with ECHO-QGP

High Energy Physics - Phenomenology 2015-06-22 v2 Nuclear Theory

Abstract

We present a numerical code modeling the evolution of the medium formed in relativistic heavy ion collisions, ECHO-QGP. The code solves relativistic hydrodynamics in (3+1)(3+1)-D, with dissipative terms included within the framework of Israel-Stewart theory; it can work both in Minkowskian and in Bjorken coordinates. Initial conditions are provided through an implementation of the Glauber model (both Optical and Monte Carlo), while freezeout and particle generation are based on the Cooper-Frye prescription. The code is validated against several test problems and shows remarkable stability and accuracy with the combination of a conservative (shock-capturing) approach and the high-order methods employed. In particular it beautifully agrees with the semi-analytic solution known as Gubser flow, both in the ideal and in the viscous Israel-Stewart case, up to very large times and without any ad hoc tuning of the algorithm.

Keywords

Cite

@article{arxiv.1408.0186,
  title  = {Heavy Ion Collision evolution modeling with ECHO-QGP},
  author = {Valentina Rolando and Gabriele Inghirami and Andrea Beraudo and Luca Del Zanna and Francesco Becattini and Vinod Chandra and Arturo De Pace and Marzia Nardi},
  journal= {arXiv preprint arXiv:1408.0186},
  year   = {2015}
}

Comments

4 pages, 6 figures, XXIV Quark Matter conference proceedings (2014)

R2 v1 2026-06-22T05:18:27.928Z