Effect of Light Nuclei on Chemical Freeze-out Parameters at RHIC Energies

Abstract

In this study, the chemical freeze-out of hadrons, including light-and strange-flavor particles and light nuclei, produced in Au+Au collisions at the Relativistic Heavy Ion Collider (RHIC), was investigated. Using the thermal-FIST thermodynamic statistical model, we analyzed various particle sets: those inclusive of light nuclei, those exclusive to light nuclei, and those solely comprising light nuclei. We determined the chemical freeze-out parameters at sNN= 7.7--200 GeV and four different centralities. A significant finding was the decrease in the chemical freeze-out temperature Tch with light nuclei inclusion, with an even more pronounced reduction when considering light nuclei yields exclusively. This suggests that light nuclei formation occurs at a later stage in the system's evolution at RHIC energies. We present parameterized formulas that describe the energy dependence of Tch and the baryon chemical potential μB for three distinct particle sets in central Au+Au collisions at RHIC energies. Our results reveal at least three distinct Tch at RHIC energies correspond to different freeze-out hypersurfaces: a light-flavor freeze-out temperature of TL = 150.26 MeV, a strange-flavor freeze-out temperature Ts = 165.12.7 MeV, and a light-nuclei freeze-out temperature Tln = 141.71.4 MeV. Notably, at the Large Hadron Collider (LHC) Pb+Pb 2.76 TeV, the expected lower freeze-out temperature for light nuclei was not observed; instead, the Tch for light nuclei was found to be approximately 10 MeV higher than that for light-flavor hadrons.