Abstract
The system-size dependence of hadrochemistry at vanishing baryon density is considered within the canonical statistical model (CSM) with local exact conservation of three conserved charges, allowing for a possibility of strangeness undersaturation, i.e. $\gamma_S \leq 1$. Exact baryon number conservation is found to be even more important than that of strangeness in the canonical suppression picture at the LHC, in contrast to intermediate and low collision energies. The model is applied to p-p, p-Pb, and Pb-Pb data of the ALICE collaboration. A chemical equilibrium CSM with a fixed $T_{\rm ch} = 155$ MeV describes the trends seen in most yield ratios. However, this vanilla version of CSM predicts an enhancement of the $\phi/\pi$ ratio at smaller multiplicities, in stark contrast to the suppression seen in the data. The data are described with a 15% relative accuracy level whence a multiplicity dependence of both the temperature and the strangeness saturation parameter $\gamma_S \leq 1$ is accepted. Both the canonical suppression and the strangeness undersaturation effects are small at $d N_{\rm ch} / d\eta \gtrsim 100$, but they do improve substantially the description of hadron yields in p-p collisions, in particular the $\Omega$ yields. A possibility to constrain the rapidity correlation volume using net-proton fluctuation measurements is pointed out.
Highlights
A rich body of experimental data on the production of light flavor hadrons produced at CERN Large Hadron Collider (LHC) energies have recently become available, through the analysis of p-p [1], p-Pb [2,3,4], and Pb-Pb [5,6,7,8] collisions
We analyzed the multiplicity dependence of the hadron yields measured by the ALICE Collaboration at the LHC within the statistical model with exact conservation of baryon number, electric charge, and strangeness
We find that the conservation of baryon number is at least as important as the exact strangeness conservation in the canonical-statistical picture at the LHC
Summary
A rich body of experimental data on the production of light flavor hadrons produced at CERN Large Hadron Collider (LHC) energies have recently become available, through the analysis of p-p [1], p-Pb [2,3,4], and Pb-Pb [5,6,7,8] collisions This comprehensive set of multiplicity-dependent data does allow for a detailed test of production models. The centrality dependence of the chemical freeze-out temperature is usually neglected in the grand-canonical statistical approach, the same constant hadron yield ratios are predicted for all multiplicities This cannot describe the observed data, in particular the enhanced. The effects of a multiplicitydependent chemical freeze-out temperature as well as incomplete chemical equilibration are considered here
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