Model study of the energy dependence of the correlation between anisotropic flow and the mean transverse momentum in Au+Au collisions

Abstract

A hybrid model that employs the hadron-string transport model UrQMD and the (3+1)D relativistic viscous hydrodynamic code vHLLE, is used to investigate the beam energy dependence of the correlation coefficient (v22,[pT]) between the average transverse momentum [pT] of hadrons emitted in an event and the square of the anisotropic flow coefficient v22. For Au+Au collisions, the model predicts characteristic patterns for the energy and event-shape dependence of the variances for [pT] and vn2 ( Var([pT]) and Var(v22)), and the covariance of vn2 and [pT] ( cov(v22,[pT])), consistent with the attenuation effects of the specific shear viscosity η/s. In contrast, (v22,[pT]) is predicted to be insensitive to the beam energy but sensitive to the initial-state geometry of the collisions. These observations suggest that a precise set of measurements for Var([pT]), Var(v22), cov(v22,[pT]) and (v22,[pT]) as a function of beam-energy and event-shape, could aid precision extraction of the temperature and baryon chemical-potential dependence of η/s from the wealth of Au+Au data obtained in the RHIC beam energy scan.