Abstract
In this work, we revisit the thermodynamical self-consistency of the quasiparticle model with the finite baryon chemical potential adjusted to lattice QCD calculations. Here, we investigate the possibility that the effective quasiparticle mass is also a function of its momentum, $k$, in addition to temperature $T$ and chemical potential $\mu$. It is found that the thermodynamic consistency can be expressed in terms of an integro-differential equation concerning $k$, $T$, and $\mu$. We further discuss two special solutions, both can be viewed as sufficient condition for the thermodynamical consistency, while expressed in terms of a particle differential equation. The first case is shown to be equivalent to those previously discussed by Peshier et al. The second one, obtained through an ad hoc assumption, is an intrinsically different solution where the particle mass is momentum dependent. These equations can be solved by using boundary condition determined by the lattice QCD data at vanishing baryon chemical potential. By numerical calculations, we show that both solutions can reasonably reproduce the recent lattice QCD results of the Wuppertal-Budapest and HotQCD Collaborations, and in particular, those concerning finite baryon density. Possible implications are discussed.
Highlights
The quasiparticle approach is part of the efforts to understand the physics of the quark-hadron transition characterized by a dramatic change in the number of degrees of freedom where nonperturbative effects are dominant
These equations can be solved by using boundary condition determined by the lattice quantum chromodynamics (QCD) data at vanishing baryon chemical potential. We show that both solutions can reasonably reproduce the recent lattice QCD results of the Wuppertal-Budapest and HotQCD Collaborations, and in particular, those concerning finite baryon density
In this work we study the thermodynamic consistency of the quasiparticle model and its implications on quasiparticle mass
Summary
The quasiparticle approach is part of the efforts to understand the physics of the quark-hadron transition characterized by a dramatic change in the number of degrees of freedom where nonperturbative effects are dominant. It is found that as the temperature decreases while the system approaches the transition region, cs reaches down to a minimum and increases again in accordance with the hadronic resonance gas (HRG) description of the system [2] Since these thermodynamical properties may lead to observable consequences through their impact on the hydrodynamically expanding phase during the relativistic heavy ion collisions, they are, essential features in the study of the strongly interacting QGP matter. The issue can be resolved by reformulating the thermodynamics of the quasiparticle model through the requirement of an exact cancellation between the additional contributions from the temperature-dependent particle mass and those from the bag constant. The latter is assumed to be temperature dependent and determined by the condition of thermodynamic consistency. The last section is devoted to discussions and concluding remarks
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