Nuclear system size scan for freeze-out properties in relativistic heavy-ion collisions by using a multiphase transport model

Abstract

A system size scan program was recently proposed for the STAR experiments at the Relativistic Heavy Ion Collider(RHIC). In this study, we employ a multiphase transport (AMPT) model for considering the bulk properties at the freeze-out stage for 10B+10B, 12C+12C, 16O+16O, 20Ne+20Ne, 40Ca+40Ca, 96Zr+96Zr, and 197Au+197Au collisions at RHIC energies sNN of 200, 20, and 7.7 GeV. The results for 197Au+197Au collisions are comparable with those of previous experimental STAR data. The transverse momentum pT spectra of charged particles (π, K, p, and p) at the kinetic freeze-out stage, based on a blast-wave model, are also discussed. In addition, we use a statistical thermal model to extract the parameters at the chemical freeze-out stage, which agree with those from other thermal model calculations. It was found that there is a competitive relationship between the kinetic freeze-out parameter Tkin and the radial expansion velocity βT, which also agrees with the STAR or ALICE results. We found that the chemical freeze-out strangeness potential μs remains constant in all collision systems and that the fireball radius R is dominated by NPart, which can be well fitted by a function of a NPartb with b ≈ 1/3. In addition, we calculated the nuclear modification factors for different collision systems with respect to the 10B + 10B system, and found that they present a gradual suppression within a higher pT range from small to large systems.