Bayesian inference of the incompressibility, skewness and kurtosis of nuclear matter from empirical pressures in relativistic heavy-ion collisions

Abstract

Within the Bayesian statistical framework we infer the incompressibility K0, skewness J0 and kurtosis Z0 parameters of symmetric nuclear matter (SNM) at its saturation density 0 using the constraining bands on the pressure in cold SNM in the density range of 1.30 to 4.50 from transport model analyses of kaon production and nuclear collective flow in relativistic heavy-ion collisions. As the default option assuming the K0, J0 and Z0 have Gaussian prior probability distribution functions (PDFs) with the means and variances of 235 30, -200 200 and -146 1728 MeV, their posterior most probable values are narrowed down to 192+12-16 MeV, -180+100-110 MeV and 200+250-250 at 68\% confidence level, respectively. The results are largely independent of the prior PDFs of J0 and Z0 used. However, if one adopts the strong belief that the incompressibility K0 has a uniform prior PDF within its absolute boundary of 220-260 MeV as one can find easily in the literature, the posterior most probable values of K0, J0 and Z0 shift to K0=220+6-0 MeV, J0=-390+60-70 MeV and Z0=600+200-200 MeV, respectively. While the posterior PDFs of the SNM EOS parameters depend somewhat on the prior PDF of K0 used, the results from using different prior PDFs are qualitatively consistent. The uncertainties of all three parameters are significantly reduced especially for the J0 and Z0 parameters compared to their current values.