The energy and scale dependence of q and the JET puzzle

Abstract

We present an attempt to probe the underlying structure of the quark-gluon plasma (QGP) at high resolution, based on the extracted jet transport coefficient q. We argue that the exchanged momentum k between the hard parton and the medium varies over a range of scales, and for k≥ 1 GeV, q can be expressed in terms of a parton distribution function (PDF). Because the mass of a QGP constituent is unknown, we define a scaling variable xN to represent the ratio of the parton momentum to the momentum of a self-contained section of the plasma which has a mass of 1 GeV. This scaling variable is used to parametrize the QGP-PDF. Calculations, based on this reconstructed q are compared to data sensitive to the hardcore of jets i.e., the single hadron suppression in terms of the nuclear modification factor RAA and the azimuthal anisotropy parameter v2, as a function of transverse momentum pT, centrality and energy of the collision. It is demonstrated that the scale evolution of the QGP-PDF is responsible for the reduction in the normalization of q between fits to Relativistic Heavy-Ion Collider (RHIC) and Large Hadron Collider (LHC) data; a puzzle, first discovered by the JET collaboration.