Sequential melting of charmonium states in an expanding Quark Gluon Plasma and J/ suppression at RHIC and LHC energy collisions

Abstract

We have developed a hydrodynamic model to study sequential melting of charmonium states in an expanding QGP medium. According to the initial fluid temperature profile, J/'s are randomly distributed in the transverse plane. As the fluid evolve in time, the free streaming J/'s are suppressed if the local fluid temperature exceed a critical temperature. PHENIX data on the centrality dependence of J/ suppression in Au+Au collisions at mid-rapidity are explained by sequential melting of the charmonium states, c, and J/, in the expanding medium. The critical temperatures TJ/ ≈2.09Tc and T=T_c=T ≈ 1.1Tc agree with lattice motivated calculations. The feed-down fraction F depend on whether the cold nuclear matter effect is included or not. It changes from F=0.3 with cold nuclear matter effect included to F=0.5 when the effect is neglected. Model fails to reproduce the PHENIX data on the centrality dependence of J/ suppression in Cu+Cu collisions at mid-rapidity, indicating that the mechanism of J/ suppression is different in Au+Au and in Cu+Cu collisions. We also use the model to predict for the centrality dependence of J/ suppression in Pb+Pb collisions at LHC energy, s=5500 GeV. In LHC energy, J/'s are more suppressed in mid central collisions than in Au+Au collisions at RHIC energy.