Multiplicity of the doubly charmed state Tcc + in heavy-ion collisions

Abstract

We study the evolution of the doubly charmed state Tcc+ in a hot hadron gas produced in the late stage of heavy-ion collisions. We use effective Lagrangians to calculate the thermally averaged cross sections of Tcc+ production in reactions such as D(*) D(*) → Tcc+ π, Tcc+ and its absorption in the corresponding inverse processes. We then solve the rate equation to follow the time evolution of the Tcc+ multiplicity, and determine how it is affected by the considered reactions during the expansion of the hadronic matter. We compare the evolution of the Tcc+ abundance treated as a hadronic S-wave molecule and as a tetraquark state. Our results show that the tetraquark yield increases by a factor of about 2 at freeze-out, but it is still one order of magnitude smaller than the final yield of molecules formed from hadron coalescence. Also, the results indicate that NTcc is more affected by interactions with hadronic medium than NX(3872) in similar conditions. We also show that yields depend very weakly on the system size, represented by N = [ d Nch / d η (η < 0.5)]1/3.