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Effective kinetic description of event-by-event pre-equilibrium dynamics in high-energy heavy-ion collisions

arXiv:1805.00961 · doi:10.1103/PhysRevC.99.034910

Abstract

We develop a macroscopic description of the space-time evolution of the energy-momentum tensor during the pre-equilibrium stage of a high-energy heavy-ion collision. Based on a weak coupling effective kinetic description of the microscopic equilibration process (à la "bottom-up"), we calculate the non-equilibrium evolution of the local background energy-momentum tensor as well as the non-equilibrium linear response to transverse energy and momentum perturbations for realistic boost-invariant initial conditions for heavy ion collisions. We demonstrate how this framework can be used on an event-by-event basis to propagate the energy momentum tensor from far-from-equilibrium initial state models, e.g. IP-Glasma, to the time $τ_\text{hydro}$ when the system is well described by relativistic viscous hydrodynamics. The subsequent hydrodynamic evolution becomes essentially independent of the hydrodynamic initialization time $τ_\text{hydro}$ as long as $τ_\text{hydro}$ is chosen in an appropriate range where both kinetic and hydrodynamic descriptions overlap. We find that for $\sqrt{s_{NN}}=2.76\,\text{TeV}$ central Pb-Pb collisions, the typical time scale when viscous hydrodynamics with shear viscosity over entropy ratio $η/s=0.16$ becomes applicable is $τ_\text{hydro}\sim 1\,\text{fm/c}$ after the collision.

45 pages, 27 figures, for the code of linear kinetic theory propagator KoMPoST used for this study see https://github.com/KMPST/KoMPoST