Artículos de revistas
Energy loss, equilibration, and thermodynamics of a baryon rich strongly coupled quark-gluon plasma
Fecha
2016-04-01Registro en:
Journal of High Energy Physics, v. 2016, n. 4, 2016.
1029-8479
1126-6708
10.1007/JHEP04(2016)102
2-s2.0-84963721660
Autor
Universidade de São Paulo (USP)
University of Oxford
Universidade do Estado de São Paulo
Columbia University
Institución
Resumen
Abstract: Lattice data for the QCD equation of state and the baryon susceptibility near the crossover phase transition (at zero baryon density) are used to determine the input parameters of a 5-dimensional Einstein-Maxwell-Dilaton holographic model that provides a consistent holographic framework to study both equilibrium and out-of-equilibrium properties of a hot and baryon rich strongly coupled quark-gluon plasma (QGP). We compare our holographic equation of state computed at nonzero baryon chemical potential, μB , with recent lattice calculations and find quantitative agreement for the pressure and the speed of sound for μB ≤ 400 MeV. This holographic model is used to obtain holographic predictions for the temperature and μB dependence of the drag force and the Langevin diffusion coefficients associated with heavy quark jet propagation as well as the jet quenching parameter q and the shooting string energy loss of light quarks in the baryon dense plasma. We find that the energy loss of heavy and light quarks generally displays a nontrivial, fast-varying behavior as a function of the temperature near the crossover. Moreover, energy loss is also found to generally increase due to nonzero baryon density effects even though this strongly coupled liquid cannot be described in terms of well defined quasiparticle excitations. Furthermore, to get a glimpse of how thermalization occurs in a hot and baryon dense QGP, we study how the lowest quasinormal mode of an external massless scalar disturbance in the bulk is affected by a nonzero baryon charge. We find that the equilibration time associated with the lowest quasinormal mode decreases in a dense medium.