Particles multiplicity based on rapidity in Landau and artificial neural network (ANN) models
International Journal of Modern Physics A • 2022
Publication Information
Authors
Not Available
Keywords
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Journal
International Journal of Modern Physics A
Publisher
world scientific
Volume
37
Issue
Not Available
Pages
2250002
publication.type
International
Paper Link
Not Available
Supplementary Materials
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Abstract
In this paper, artificial neural network (ANN) model is used to estimate the multiplicity
per rapidity for charged pions and kaons observed in various high-energy experiments
from central Au+Au heavy-ion collisions with energies ranging from 2–200 GeV, and
then compared to available experimental data, including RHIC-BRAHMS experiment,
and covering the energy range of the future accelerator facilities at NICA and FAIR.
We also used Landau hydrodynamical approach, which has a better description for the
evolution of hot and dense matter produced in ultra-relativistic heavy-ion collisions.
The approach is fitted to both results estimated from experiment and ANN simulation.
We noted that the Landau model accurately reproduces the entire range of multiplicity
per rapidity for all created particles at all energies. Also ANN model can reproduce the
multiplicity per rapidity very well for all the considered particles. This encourages us to use ANN model to predict the multiplicity per rapidity for k− particles at energies 12.2
and 17.3 GeV.
per rapidity for charged pions and kaons observed in various high-energy experiments
from central Au+Au heavy-ion collisions with energies ranging from 2–200 GeV, and
then compared to available experimental data, including RHIC-BRAHMS experiment,
and covering the energy range of the future accelerator facilities at NICA and FAIR.
We also used Landau hydrodynamical approach, which has a better description for the
evolution of hot and dense matter produced in ultra-relativistic heavy-ion collisions.
The approach is fitted to both results estimated from experiment and ANN simulation.
We noted that the Landau model accurately reproduces the entire range of multiplicity
per rapidity for all created particles at all energies. Also ANN model can reproduce the
multiplicity per rapidity very well for all the considered particles. This encourages us to use ANN model to predict the multiplicity per rapidity for k− particles at energies 12.2
and 17.3 GeV.
Staff Members - Benha University