The shear viscosity of parton matter under anisotropic scatterings

Abstract

The shear viscosity η of a quark-gluon plasma in equilibrium can be calculated analytically using multiple methods or numerically using the Green-Kubo relation. It has been realized, which we confirm here, that the Chapman-Enskog method agrees well with the Green-Kubo result for both isotropic and anisotropic two-body scatterings. We then apply the Chapman-Enskog method to study the shear viscosity of the parton matter from a multi-phase transport model. In particular, we study the parton matter in the center cell of central and midcentral Au+Au collisions at 200A GeV and Pb+Pb collisions at 2760A GeV, which is assumed to be a plasma in thermal equilibrium but partial chemical equilibrium. As a result of using a constant Debye mass or cross section σ for parton scatterings, the η/s ratio increases with time (as the effective temperature decreases), contrary to the trend preferred by Bayesian analysis of the experimental data or pQCD results that use temperature-dependent Debye masses. At σ=3 mb that enables the transport model to approximately reproduce the elliptic flow data of the bulk matter, the average η/s of the parton matter in partial equilibrium is found to be very small, between one to two times 1/(4π).