Production of open-charm mesons in relativistic heavy-ion collisions

Abstract

We present a theoretical framework to study open charm production in relativistic heavy-ion collisions. The coupling strength between the charm quarks and the QGP constituents, quantified by the spatial diffusion coefficient 2π TDs, is obtained by performing a phenomenological fit analysis to the lattice QCD calculations, resulting in 2π TDs=const. (Model-A) and 2π TDs=1.3 + (T/Tc)2 (Model-B). We find that the relative azimuthal distribution of the initially back-to-back generated cc pairs presents a broadening behaviour, which is more pronounced for cc pairs with small initial p T, and when the Model-B approach is adopted. The competition between the initial drag and the subsequent collective effects tends to restrict the time dependence of charm quark R AA. Concerning the theoretical uncertainty on final D-meson nuclear modification, the nuclear shadowing and pp baseline components are dominat at high and low p T (p T3~ GeV/ c), respectively. The measured D-meson R AA(p T) favors Model-A assumption for the diffusion coefficient both at RHIC and LHC, while their v2(p T) prefer Model-B at moderate p T. These results confirm the necessity to consider the temperature- and/or momentum-dependence of 2π TDs to describe well the D-meson R AA and v 2 simultaneously.