A Rating Quality Methodology for the Theoretical Description of Experimental Data

Abstract

We introduce a novel multi-parameter rating methodology for comparing theoretical models with experimental data in heavy-ion collisions, addressing limitations of the global 2/ndf criterion. The methodology divides phase space into seven physically motivated kinematic zones. Each zone receives a quality score Qi ∈ [10, 1000] via logarithmic transformation of local 2i/i statistics. A composite rating R aggregates weighted average, geometric mean, and minimum scores with a bounded dispersion penalty. The seven-zone division is validated through boundary significance tests on CMS PbPb data at sNN = 5.02 TeV: four of six physical boundaries are confirmed significant (p < 0.05) while none of the data-driven K=9 candidates carry independent physical significance. Coefficient sensitivity: 20\% variations produce R < 2\% with zero rank changes. Applied to ALICE data for K0S mesons and hyperons in p-Pb at sNN = 5.02 TeV, the methodology reveals a hierarchy of model universality: PHSD (microscopic QGP transport + coalescence) achieves near-universal performance (R=911 for mesons, R=893 for baryons on a synthetic LHCb-kinematics benchmark), while PYTHIA8 (R=878) leads in the hard-fragmentation regime via nuclear PDFs. The baryon anomaly peak in zones 3--4 yields Qi 950--1000 for coalescence models versus Qi 400--600 for fragmentation generators. The near-universal performance of PHSD demonstrates that coalescence mechanisms are critical not only for baryon production but also for a globally consistent description of meson spectra. The methodology is transparent, reproducible, and ready for integration into standard analysis frameworks.