System-size dependence of the D0--Ds+ flow splitting from early Ds+ formation at sNN = 5.36~TeV

Abstract

We investigate the elliptic-flow splitting between prompt D0 and Ds+ mesons within a heavy-quark transport framework with sequential hadronization, in which Ds+ forms at 1.2\,Tc and D0 at Tc. We present predictions for the pT-differential v2 and Ds+/D0 yield ratio in O--O 0--20\% collisions at sNN = 5.36~TeV, where preliminary ALICE data are available. The sequential scenario reproduces the observed v2(D0) > v2(Ds+) ordering and predicts an enhanced Ds+/D0 ratio at low pT, whereas a simultaneous baseline yields the opposite ordering. Decomposing the hadronic splitting into its partonic components, we show that the v2 ordering is driven by the late-stage flow accumulated by D0-parent charm quarks during the 1.2\,Tc Tc interval, with hadronic rescattering essential to preserve the signal in small systems. A systematic scan across nine collision configurations spanning O--O and Pb--Pb centralities reveals a universal linear scaling between the hadronic splitting and the partonic flow increment accumulated during this window. This establishes the D0--Ds+ flow splitting as a hadronization chronometer of the QGP at sNN = 5.36~TeV.