Equation of state, universal profiles, scaling and macroscopic quantum effects in Warm Dark Matter galaxies

Abstract

The Thomas-Fermi approach to galaxy structure determines selfconsistently and nonlinearly the gravitational potential of the fermionic WDM particles given their quantum distribution function f(E). Galaxy magnitudes as the halo radius rh, mass Mh, velocity dispersion and phase space density are obtained. We derive the general equation of state for galaxies (relation between the pressure and the density), and provide an analytic expression. This clearly exhibits two regimes: (i) Large diluted galaxies for Mh > 2.3 106 Msun corresponding to temperatures T0 > 0.017 K, described by the classical self gravitating WDM Boltzman regime and (ii) Compact dwarf galaxies for 1.6 106 Msun > Mh>Mh,min=30000 (2keV/m)16/5 Msun, T0<0.011 K described by the quantum fermionic WDM regime. The T0=0 degenerate quantum limit predicts the most compact and smallest galaxy (minimal radius and mass Mh,min). All magnitudes in the diluted regime exhibit square root of Mh scaling laws and are universal functions of r/rh when normalized to their values at the origin or at rh. We find that universality in galaxies (for Mh > 106 Msun) reflects the WDM perfect gas behaviour. These theoretical results contrasted to robust and independent sets of galaxy data remarkably reproduce the observations. For the small galaxies, 106>Mh>Mh,min corresponding to effective temperatures T0 < 0.017 K, the equation of state is galaxy dependent and the profiles are no more universal. These non-universal properties in small galaxies account to the quantum physics of the WDM fermions in the compact regime. Our results are independent of any WDM particle physics model, they only follow from the gravitational interaction of the WDM particles and their fermionic quantum nature.