Heavy Quarkonia in Quark-Gluon Plasma

Abstract

Using the color-singlet free energy F1 and total internal energy U1 obtained by Kaczmarek et al. for a static quark Q and an antiquark Qbar in quenched QCD, we study the binding energies and wave functions of heavy quarkonia in a quark-gluon plasma. By minimizing the grand potential in a simplified schematic model, we find that the proper color-singlet Q-Qbar potential can be obtained from the total internal energy U1 by subtracting the gluon internal energy contributions. We carry out this subtraction in the local energy-density approximation in which the gluon energy density can be related to the local gluon pressure by the quark-gluon plasma equation of state. We find in this approximation that the proper color-singlet Q-Qbar potential is approximately F1 for T ~ Tc and it changes to (3/4)F1+(1/4)U1 at high temperatures. In this potential model, the J/psi is weakly bound above the phase transition temperature Tc, and it dissociates spontaneously above 1.62 Tc, while chic and psi' are unbound in the quark-gluon plasma. The bottomium states Upsilon, chib and Upsilon' are bound in the quark-gluon plasma and they dissociate at 4.10 Tc, 1.18 Tc, and 1.38 Tc respectively. For comparison, we evaluate the heavy quarkonium binding energies also in other models using the free energy F1 or the total internal energy U1 as the Q-Qbar potential. The comparison shows that the model with the new Q-Qbar potential proposed in this manuscript gives dissociation temperatures that agree best with those from spectral function analyses. We evaluate the cross section for sigma(g+J/psi->c+cbar) and its inverse process, in order to determine the J/psi dissociation width and the rate of J/psi production by recombining c and cbar in the quark gluon plasma.

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