Insights on pion production mechanism and symmetry energy at high density

Abstract

The N NN cross sections, which take into account the -mass dependence of M-matrix and momentum pN, are applied on the calculation of pion production within the framework of the UrQMD model. Our study shows that UrQMD calculations with the -mass dependent N NN cross sections enhance the pion multiplicities and decrease the π-/π+ ratios. By analyzing the time evolution of the pion production rate and the density in the overlapped region for Au+Au at the beam energy of 0.4A GeV, we find that the pion multiplicity probes the symmetry energy in the region of 1-2 times normal density. The process of pion production in the reaction is tracked including the loops of NN N and Nπ, our calculations show that the sensitivity of π-/π+ to symmetry energy is weakened after 4-5 N--π loops in the pion production path, while the π-/π+ ratio in reactions at near threshold energies remains its sensitivity to the symmetry energy. By comparing the calculations to the FOPI data, we obtain a model dependent conclusion on the symmetry energy and the symmetry energy at two times normal density is S(20)=38-73 MeV within 1σ uncertainties. Under the constraints of tidal deformability and maximum mass of neutron star, the symmetry energy at two times normal density is reduced to 48-58 MeV and slope of symmetry energy L=54-81 MeV, and it is consistent with the constraints from ASY-EOS flow data.