Tracing pT-differential radial flow from blast-wave analytics to quark coalescence

Abstract

The observable v0(), which quantifies event-by-event fluctuations in the differential transverse-momentum spectrum, is proposed as a direct and penetrating probe of radial flow in heavy-ion collisions. Recent measurements at the LHC exhibit a clear mass ordering for pions, kaons and protons at low and a baryon-meson splitting at intermediate , resembling to the well-known features of elliptic flow (v2). In this letter, we first derive an analytic expression of v0() within a Blast-Wave framework incorporating fluctuations of freeze-out temperature and radial expansion velocity, which can naturally explains the experimentally observed mass ordering. The distinct dynamical origins of the mass ordering in v0() and v2() are discussed. Furthermore, using the AMPT model, we demonstrate that the baryon-meson splitting emerges spontaneously from the quark coalescence. This study provides deeper insight into the v0() observable and the collective dynamics of the QGP.