Flattenicity as "centrality" estimator in p-Pb collisions simulated with PYTHIA 8.312 Angantyr
Abstract
In this paper, a "centrality" estimator based on flattenicity () is studied in proton-led (p-Pb) collisions at s NN=5.02 TeV using PYTHIA 8 Angantyr. Although Angantyr is still under development, the existing implementation is enough to study the particle production in systems where medium effects are absent. Firstly, ALICE data on pseudorapidity distributions as a function of the forward multiplicity (V0M), as well as transverse momentum distributions of identified particles in non-single diffractive p-Pb collisions, are compared with Angantyr. Secondly, the average number of binary nucleon-nucleon (N coll) collisions for different "centrality" estimators are compared. The studies include the following "centrality" estimators: V0M, and midrapidity multiplicity (CL1). On one hand, the "centrality" dependence of N coll for the selection shows the smallest deviations (<8 %) with respect to that obtained using impact parameter b; on the other hand, the V0M and CL1 yield huge deviations (up to a factor 2) with respect to the results using b. The particle ratios and nuclear modification factors (Q pPb) as a function of p T are also studied. The proton-to-pion ratio exhibits a flow-like peak at intermediate p T (2-8 GeV/c) with little or no "centrality" dependence for V0M, and b selections. The kaon-to-pion ratio as a function of p T is "centrality" independent for the same selections. On the contrary, for the CL1 class the ratios exhibit the typical behaviour associated with hard physics. Regarding Q pPb, a peak at intermediate p T (2-8 GeV/c) for different particle species is observed when the "centrality" is obtained with b or . The observed features diminish for the selections based on V0M and CL1.
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