Testing of KNO-scaling of charged hadron multiplicities within a Machine Learning based approach
G. Biro*, B. Tankó-Bartalis and G.G. Barnaföldi
Pre-published on:
October 20, 2022
Published on:
June 15, 2023
Abstract
The results of a Machine Learning-based method is presented here to investigate the scaling properties of the final state charged hadron and mean jet multiplicity distributions. Deep residual neural network architectures with different complexities are utilized to predict the final state multiplicity distribution from the parton-level final state, generated by the Pythia Monte Carlo event generator. Hadronization networks were trained by √s = 7 TeV events, while predictions have been made for various LHC energies from √s = 0.9 TeV to 13 TeV. Scaling properties were adopted by the networks at hadronic level, indeed KNO-scaling is preserved—although, the scaling of the mean jet multiplicity distributions varies for the applied models.
DOI: https://doi.org/10.22323/1.414.1188
How to cite
Metadata are provided both in "article" format (very similar to INSPIRE) as this helps creating
very compact bibliographies which can be beneficial to authors and
readers, and in "proceeding" format
which is more detailed and complete.