Constraints on the Path-Length Dependence of Jet Quenching in Nuclear Collisions at RHIC and LHC

Abstract

Recent data on the high-pT pion nuclear modification factor, RAA(pT), and its elliptic azimuthal asymmetry, v2(pT), from RHIC/BNL and LHC/CERN are analyzed in terms of a wide class of jet-energy loss models coupled to different (2+1)d transverse plus Bjorken expanding hydrodynamic fields. We test the consistency of each model by demanding a simultaneous account of the azimuthal, the transverse momentum, and the centrality dependence of the data at both 0.2 and 2.76 ATeV energies. We find a rather broad class of jet-energy independent energy-loss models dE/dx= (T) xz T2+z ζq that, when coupled to bulk constrained temperature fields T(x,t), can account for the current data at the 2<2 level with different temperature-dependent jet-medium couplings and path-length dependence exponents 0 z 2. We test the sensitivity of predictions to different skewed energy-loss fluctuations via a convenient scaling factor distributed in a finite range 0< ζq < 2+q with unit mean. While a previously proposed AdS/CFT jet-energy loss model with a temperature-independent jet-medium coupling as well as a near-Tc dominated, pQCD-inspired energy-loss scenario are shown to be inconsistent with the LHC data, once the parameters are constrained by fitting to RHIC results, we find several new solutions with a temperature-dependent jet-medium coupling. We conclude that the current level of statistical and systematic uncertainties of the measured data does not allow a constraint on the path-length exponent z to a range narrower than [0-2].