HIC for FAIR logo Nuclear Physics Colloquium

Location:  Physics Building Science Campus Riedberg, Max-von-Laue-Str. 1, room PHYS  2.116
Time: Thursday, October 24, 2013,  4:30-5:30pm
(plus 10min for discussion)
Contact: hees@fias.uni-frankfurt.de



Onset of hydrodynamical behavior in heavy ion collisions

Thomas Epelbaum (CEA)


The heavy ion collisions performed at the RHIC and the LHC are among the most impressive experimental achievements ever performed in physics. In those two rings, heavy ions (lead, gold...) are smashed onto one another at a speed that almost reaches the one of light. The analysis performed on the products of these collisions are of great interest for understanding Quantum Chromodynamics (QCD) at very high energies.

During the past ten years or so, the RHIC and the LHC have more or less established a striking feature of the collision products. These latters – referred as the Quark Gluon Plasma, or QGP – seem to behave like a nearly perfect fluid, and do so after a very short transient time: less than 1 fm/c. This is assumed to be the case, because relativistic hydrodynamics with a very small value of shear viscosity has been such a successful theory to describe the experimental data. In the meantime, theoretical models based on QCD have so far failed to predict such a hydrodynamical behavior. The one that we will come to use – the Color Glass Condensate (CGC) effective theory – even predict at its Leading Order (LO) a negative longitudinal pressure of the system at the initial time, with a value opposite to the energy density and the transverse pressure. By contrast, hydrodynamics has among its postulates a small anisotropy of the system. This apparent paradox between theory and experiment has yet to receive a satisfying answer. Improvements of the CGC are therefore needed.

We will report here recent analytical and numerical progress performed within this CGC framework, showing in particular that an early isotropization of the system is possible.


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