Transport coefficients of strongly interacting quark-gluon plasma including elastic and inelastic scattering within the dynamical quasiparticle model

Abstract

We study the impact of inelastic gluon-radiation processes on the transport coefficients of the quark-gluon plasma within the dynamical quasiparticle model (DQPM) in the temperature-baryon-chemical-potential plane (T,μB). Extending the elastic baseline established in previous DQPM calculations, we include radiative 23 scattering channels with massive partons and effective DQPM propagators and vertices. The corresponding momentum-dependent interaction rates and relaxation times are used within the relaxation-time approximation to calculate the shear viscosity, bulk viscosity, electric conductivity, and baryon diffusion coefficient as functions of temperature T and baryon chemical potential μB. We find that radiative channels systematically reduce all considered transport coefficients relative to the elastic-only results, in accordance with the decrease of the relaxation times. In the thermal regime explored here, however, this reduction remains moderate, since the inelastic rates stay below the elastic ones over the considered (T,μB) range. The radiative channels become more relevant mainly for partonic scatterings at large momenta, which are thermally suppressed in the strongly interacting QGP. At μB=0, the resulting η/s, ζ/s, and σQ/T are compatible with available lattice-QCD estimates within uncertainties. At finite μB, our results provide predictions for the transport properties of QCD matter relevant for beam-energy-scan programs.