Production of doubly charmed hadron cc++ and Tcc+ in relativistic heavy ion collisions

Abstract

Heavy ion collisions provide a unique opportunity for studying the properties of exotic hadrons with two charm quarks. The production of Tcc+ is significantly enhanced in nuclear collisions compared to proton-proton collisions due to the creation of multiple charm pairs. In this study, we employ the Langevin equation in combination with the Instantaneous Coalescence Model (LICM) to investigate the production of Tcc+ and cc++ which consists of two charm quarks. We consider Tcc+ as molecular states composed of D and D* mesons. The Langevin equation is used to calculate the energy loss of charm quarks and D mesons in the hot medium. The hadronization process, where charm quarks transform into each D state as constituents of Tcc+ production, is described using the coalescence model. The coalescence probability between D and D* is determined by the Wigner function, which encodes the information of the Tcc+ wave function. Our results show that the Tcc+ production varies by approximately one order of magnitude when different widths in the Wigner function, representing distinct binding energies of Tcc+, are considered. This variation offers valuable insights into the nature of Tcc+ through the analysis of its wave function. The cc++ is treated as a hadronic state produced at the hadronization of the deconfined matter. Its production is also calculated as a comparison with the molecular state Tcc+.