Chapman-Enskog calculation of the shear viscosity of quark-gluon plasma including all 2 2 scatterings at finite temperature

Abstract

We use the Chapman-Enskog method to investigate the shear viscosity of the quark-gluon plasma with a focus on its relation to parton cross sections. We use the recently obtained analytical expression for the shear viscosity η of a massless quark-gluon gas at chemical equilibrium with Boltzmann statistics and all 2 2 scatterings with arbitrary cross sections. Here we apply this general expression to cross sections at finite temperature that are based on perturbative-QCD and screened with scaled thermal masses \,mD and \,mF. We find that the Chapman-Enskog results on η \, g4/T3 versus mD/T at =1 are qualitatively similar to but higher than the corresponding leading-order results from the AMY framework. We then find that using =0.4 allows the Chapman-Enskog results to match well the corresponding AMY results as it includes the effect of using thermal masses (instead of self-energies) to screen the cross sections. In addition, we show that the shear viscosity-to-entropy density ratio η/s is very sensitive to the choice of momentum scale Q in the strong coupling, where the choice of Q=3T leads to η/s 0.15 for Nf=0 or 3 at the QCD phase transition temperature Tc. These results lay the foundation for mapping parton cross sections to given shear viscosity in parton transport models and QCD effective kinetic theory.