Statistical hadronization model and transverse momentum spectra of hadrons in high energy collisions

A detailed analysis of transverse momentum spectra of several identified hadrons in high energy collisions within the canonical framework of the statistical model of hadronization is performed. The study of particle. momentum spectra requires an extension of the statistical model formalism used to handle particle multiplicities, which is described in detail starting from a microcanonical treatment of single hadronizing clusters. Also, a now treatment of extra strangeness suppression is presented which is based on the enforcement of fixed numbers of s (s) over bar pairs in the primary hadrons. The considered center-of-mass energies range from similar or equal to 10 to 30 GeV in hadronic collisions (pip, pp and Kp) and from similar or equal to 15 to 35 GeV in c(+)c(-) collisions. The effect of the decay chain following hadron generation is accurately and exhaustively taken into account by a newly proposed numerical method. The exact PT conservation at low energy and the increasing hard parton emission at high energy bound the validity of the presently taken approach within a limited center-of-mass energy, range. However, within this region, a clear consistency is found between the temperature parameter extracted from the present analysis and that obtained from fits tu average hadron multiplicities in the same collision systems. This finding indicates that in the hadronization process the production of different particle species and their momentum spectra are two closely related phenomena governed by one parameter.