Identified charged hadron production in Pb-Pb collisions at $\sqrt{s_{NN}}$ = 2.76 TeV with the ALICE experiment at the LHC

Quark Gluon Plasma (QGP) is an unavoidable consequence of Quantum Chromodynamics (QCD). High-energy heavy-ion collisions offer the unique possibility to reproduce in the laboratory the conditions expected during the very first stages of the evolution of the universe. The ALICE (A Large Ion Collider Experiment) experiment at the Large Hadron Collider (LHC) allows the study of the dense nuclear environment created in nucleus-nucleus collisions. Particle Identification (PID) is one of the point of strength of the ALICE experiment. Identified particle spectra represent a crucial tool to understand the behaviour of the matter created in high-energy heavy-ion collisions. The transverse momentum $p_{ m T}$ distributions of identified hadrons contain informations about the transverse expansion of the system and constrain the freeze-out properties of the system. The ALICE Inner Tracking System (ITS) can be used as a standalone tracker with a dedicated tracking algorithm. This allows the reconstruction of particles that decay before reaching the Time Projection Chamber (TPC) or that pass through the dead zones of the TPC. Hydrodynamic models have proved to be very successful reproducing a large number of features of heavy-ion collisions (e.g. particle $p_{ m T}$ distributions, radial flow, elliptic flow, Hanbury Brown-Twiss correlations ...). The measurement of the $p_{ m T}$ distributions of identified $pi$, K and p in Pb-Pb collisions at $sqrt{s_{ m NN}}$ = 2.76 TeV is presented and discussed in terms of hydrodynamics. The VZERO detector allows the selection of events based on the eccentricity of the collision (related with the initial geometry). This makes possible the study the correlation between the $p_{ m T}$ distribution of hadrons and elliptic flow on an events-by-event basis. Hadron abundances can be obtained from the principle of maximum entropy using statistical concepts. This allows the extrapolation of the chemical freeze-out parameters from the data. Over the last years it has been proved that the chemical freeze-out temperature ${T}_{ch}$ is connected with the phase transition temperature ${T}_{C}$. The measurements of the freeze-out parameters at the LHC energy is described in detail and the results obtained by different groups at lower energies are extended with the inclusion of the LHC measurement. The LHC measurements cast a new light upon the hydrodynamic and thermal behaviour of the hadron production in heavy-ion collisions. The possible scenarios are described and commented.