Revisiting identified-particle pT spectra using the Boltzmann-Gibbs blast-wave model in a Bayesian inference framework

Abstract

We perform a Bayesian analysis of transverse momentum (pT) spectra of identified particles, i.e., pions, kaons, and protons, at midrapidity in Au+Au collisions and Pb+Pb collisions using the Boltzmann-Gibbs blast-wave (BGBW) model. We investigate whether it is possible to simultaneously describe the pT spectra of identified particles without imposing the particle species-dependent pT fit ranges -- a practice that was followed in conventional blast-wave model studies to achieve reasonable simultaneous fits. Using Bayesian analysis, our results indicate that a simultaneous description of the pT spectra of pions, kaons, and protons is feasible without imposing the particle species-dependent pT fit ranges, for Au+Au collisions up to the available data (2 GeV/c) and for Pb+Pb collisions up to 3 GeV/c. The extracted parameters remain broadly consistent with those obtained from conventional BGBW simultaneous fits, while the extension of the fit range leads to moderate changes in some parameters. Furthermore, Bayesian analysis yields well-constrained posterior distributions for the kinetic freeze-out temperature Tkin, the average transverse flow velocity βT, and the exponent of the velocity profile n and shows their correlations transparently. We suggest that the BGBW model in a Bayesian inference framework proposed can be applied in future data analyses to simultaneously describe the pT spectra of identified particles and extract the relevant information about the collision system.