RHIC has reported that relativistic heavy ion collisions produce a deconfined QCD matter called Quark-Gluon Plasma. The system created in this type of collision has properties under investigation in RHIC and CERN experiments. On the theoretical side, the THERMUS model, based on statistical mechanics, is used to extract the properties of those mediums. Here, we present the extraction of the thermodynamic properties of systems created in heavy ion collisions by studying the strangeness and non-strangeness of hadrons produced at the STAR, NA49, and AGS experiments. The extracted results are energy chemical potential, temperature energy density, and entropy. Finally, results extracted from centrality classes are also shown.

RHIC has reported that relativistic heavy ion collisions produce a deconfined QCD matter called Quark-Gluon Plasma. The system created in this type of collision has properties under investigation in RHIC and CERN experiments. On the theoretical side, the THERMUS model, based on statistical mechanics, is used to extract the properties of those mediums. Here, we present the extraction of the thermodynamic properties of systems created in heavy ion collisions by studying the strangeness and non-strangeness of hadrons produced at the STAR, NA49, and AGS experiments. The extracted results are energy chemical potential, temperature energy density, and entropy. Finally, results extracted from centrality classes are also shown.