Observational rotation curves and density profiles vs. the Thomas-Fermi galaxy structure theory

Abstract

The Thomas-Fermi approach to galaxy structure determines selfconsistently the fermionic warm dark matter (WDM) gravitational potential given the distribution function f(E). This framework is appropriate for macroscopic quantum systems: neutron stars, white dwarfs and WDM galaxies. Compact dwarf galaxies follow from the quantum degenerate regime, while dilute and large galaxies from the classical Boltzmann regime. We find analytic scaling relations for the main galaxy magnitudes as halo radius rh, mass Mh and phase space density. The observational data for a large variety of galaxies are all well reproduced by these theoretical scaling relations. For the compact dwarfs, our results show small deviations from the scaling due to quantum macroscopic effects. We contrast the theoretical curves for the circular velocities and density profiles with the observational ones. All these results are independent of any WDM particle physics model, they only follow from the gravity interaction of the WDM particles and their fermionic nature. The theory rotation and density curves reproduce very well for r < rh the observations of 10 different and independent sets of data for galaxy masses from 5x109 Msun till 5x1011 Msun. Our normalized circular velocity curves turn to be universal functions of r/rh for all galaxies and reproduce very well the observational curves for r < rh. Conclusion: the Thomas-Fermi approach correctly describes the galaxy structures (Abridged).