Chemical Potential and the Nature of the Dark Energy: The case of phantom

Abstract

The influence of a possible non zero chemical potential μ on the nature of dark energy is investigated by assuming that the dark energy is a relativistic perfect simple fluid obeying the equation of state (EoS), p=ω (ω <0, constant). The entropy condition, S ≥ 0, implies that the possible values of ω are heavily dependent on the magnitude, as well as on the sign of the chemical potential. For μ >0, the ω-parameter must be greater than -1 (vacuum is forbidden) while for μ < 0 not only the vacuum but even a phantomlike behavior (ω <-1) is allowed. In any case, the ratio between the chemical potential and temperature remains constant, that is, μ/T=μ0/T0. Assuming that the dark energy constituents have either a bosonic or fermionic nature, the general form of the spectrum is also proposed. For bosons μ is always negative and the extended Wien's law allows only a dark component with ω < -1/2 which includes vacuum and the phantomlike cases. The same happens in the fermionic branch for μ <0. However, fermionic particles with μ >0 are permmited only if -1 < ω < -1/2. The thermodynamics and statistical arguments constrain the EoS parameter to be ω < -1/2, a result surprisingly close to the maximal value required to accelerate a FRW type universe dominated by matter and dark energy (ω -10/21).