Multiplicity dependence of thermal parameters in pp collisions at s=7 TeV from statistical hadronization fits

Abstract

We perform a systematic thermal analysis of identified hadron yields measured by the ALICE Collaboration in proton-proton collisions at s=7 TeV across charged-particle multiplicity classes within the statistical hadronization model using the Thermal-FIST framework. Global fits are used to extract the chemical freeze-out temperature T, system volume V, and strangeness saturation parameter γS. The extracted temperature remains approximately constant at T 155-165 MeV across multiplicity, while the volume exhibits an approximately linear increase with event activity. In contrast, γS shows a clear rise with multiplicity, indicating a progressive reduction of strangeness suppression. Derived thermodynamic quantities obtained within the model show that the energy density increases with multiplicity, while the average energy per particle increases from 0.85 GeV to 0.99 GeV, remaining close to 1 GeV. Particle-to-pion ratios exhibit a hierarchy with strangeness content consistent with ALICE measurements. A systematic comparison of fits constrained by hidden- and open-strangeness hadrons reveals a persistent offset in γS at the 4σ level, indicating a tension between φ- and -constrained fits. These results suggest that while high-multiplicity proton-proton collisions approach thermal-like behavior, a single global freeze-out description may not fully capture the strange sector.