D-meson production via sequential hadronization in high-energy nuclear collisions

Abstract

Heavy flavor production serves as an ideal probe of the hadronization mechanism of the quark-gluon plasma created in relativistic heavy ion collisions. We study charm-quark hadronization using Langevin transport in the medium together with a sequential coalescence model. Since Ds forms earlier than D0, as obtained from the Dirac equation with an in-medium potential extracted from lattice QCD, the Ds elliptic flow v2 is smaller than the D0 v2 in the intermediate-pT region, in good agreement with the recent ALICE data. Incorporating sequential coalescence, charm-quark number conservation, and strangeness enhancement predicts a peak in the yield ratio Ds/D0 at low pT, which can be tested in future heavy-ion collisions.