Probing high-density nuclear symmetry energy with -/0 ratio in heavy-ion collisions at sNN 3 GeV

Abstract

Recent beam energy scan (BES) experiments at RHIC by the STAR Collaboration (PLB 827,137003 (2022) and PRL 128, 202303 (2022)) found that hadronic interactions dominate the collective flow and the proton cumulant ratios are driven by baryon number conservation in a region of high baryon density in sNN = 3 GeV Au+Au reactions, indicating the dense medium formed in such collisions is likely hadronic matter. Within an updated ART (A Relativistic Transport) model with momentum dependent isoscalar and isovector single-nucleon mean-field potentials corresponding to different symmetry energies at suprasaturation densities, the n/p, π-/π+, Ks0/K+, -/+ and -/0 ratios are studied for central Au+Au collisions at sNN = 3 GeV where the maximum central density reaches about (3.6 4.0)0. The doubly strange -/0 ratio is found to have the strongest sensitivity to the variation of high-density nuclear symmetry energy. Thus, the -/0 ratio in relativistic heavy-ion reactions at sNN 3 GeV may help probe sensitively the poorly known symmetry energy of dense neutron-rich matter critically important for understanding various properties of neutron stars.