Abstract
We review the charged particle and photon multiplicities and transverse energy production in heavy-ion collisions starting from few GeV to TeV energies. The experimental results of pseudorapidity distribution of charged particles and photons at different collision energies and centralities are discussed. We also discuss the hypothesis of limiting fragmentation and expansion dynamics using the Landau hydrodynamics and the underlying physics. Meanwhile, we present the estimation of initial energy density multiplied with formation time as a function of different collision energies and centralities. In the end, the transverse energy per charged particle in connection with the chemical freeze-out criteria is discussed. We invoke various models and phenomenological arguments to interpret and characterize the fireball created in heavy-ion collisions. This review overall provides a scope to understand the heavy-ion collision data and a possible formation of a deconfined phase of partons via the global observables like charged particles, photons, and the transverse energy measurement.
Highlights
At extreme temperatures and energy density, hadronic matter undergoes a phase transition to partonic phase called QuarkGluon Plasma (QGP) [1,2,3]
It is proposed that the correlation of mean transverse momentum ⟨pT⟩ and the multiplicity of the produced particles may serve as a probe for the Equation of State (EoS) of hot hadronic matter [5]
Pseudorapidity distribution of charged particles is proposed to be one of the important global observables to characterize the hot and dense medium produced in the heavyion collisions
Summary
At extreme temperatures and energy density, hadronic matter undergoes a phase transition to partonic phase called QuarkGluon Plasma (QGP) [1,2,3]. Global observables like transverse energy (ET), particle multiplicities (Nγ, Nch, etc.), pT-spectra of the produced particles, and their pseudorapidity distributions (dET/dη, dN/dη) with different colliding species and beam energies provide insight about the dynamics of the system and regarding the formation of QGP [2, 4]. The scaling of total charged particles with collision centrality and its energy dependence are discussed. This is followed with similar discussions on the photon pseudorapidity density at forward rapidities, which includes longitudinal scaling of photons. Appendix discusses the important properties of Gamma and Negative Binomial Distributions
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