Quarkonium p T spectra in heavy--ion collisions at LHC energies within a hydrodynamic core--corona framework

Abstract

We present a systematic study of the transverse momentum (p T) spectra of charmonium (J/, (2S)) and bottomonium ((nS)) states in Pb-Pb collisions at s NN = 5.02 TeV within an analytical relativistic hydrodynamics framework. The medium evolution is described assuming cylindrical symmetry with boost-invariant longitudinal expansion and Hubble-like transverse flow. Quarkonium spectra are evaluated using the Cooper-Frye formalism on a constant-temperature freeze-out hypersurface, supplemented by a core--corona approach to include both thermal and non-thermal contributions. The model describes the measurements from ALICE and CMS over a broad p T range. For charmonium, both the spectra and the (2S)/J/ ratio are well reproduced, while deviations at high p T for J/ indicate additional hard production mechanisms. In the bottomonium sector, the (nS) spectra and their yield ratios are successfully described, consistent with the expected sequential suppression pattern. These results demonstrate that an analytical hydrodynamic approach combined with a core-corona framework provides a unified and transparent description of quarkonium production in heavy--ion collisions at LHC energies.