Derivation of the core mass -- halo mass relation of fermionic and bosonic dark matter halos from an effective thermodynamical model

Abstract

We consider the possibility that dark matter halos are made of quantum particles such as fermions or bosons in the form of Bose-Einstein condensates. In that case, they generically have a "core-halo" structure with a quantum core that depends on the type of particle considered and a halo that is relatively independent of the dark matter particle and that is similar to the NFW profile of cold dark matter. We model the halo by an isothermal gas with an effective temperature T. We then derive the core mass -- halo mass relation Mc(Mv) of dark matter halos from an effective thermodynamical model by extremizing the free energy F(Mc) with respect to the core mass Mc. We obtain a general relation that is equivalent to the "velocity dispersion tracing" relation according to which the velocity dispersion in the core vc2 GMc/Rc is of the same order as the velocity dispersion in the halo vv2 GMv/rv. We provide therefore a justification of this relation from thermodynamical arguments. In the case of fermions, we obtain a relation Mc Mv1/2 that agrees with the relation found numerically by Ruffini et al.. In the case of noninteracting bosons, we obtain a relation Mc Mv1/3 that agrees with the relation found numerically by Schive et al.. In the case of bosons with a repulsive self-interaction in the Thomas-Fermi limit, we predict a relation Mc Mv2/3 that still has to be confirmed numerically. We also obtain a general approximate core mass -- halo mass relation that is valid for bosons with arbitrary repulsive or attractive self-interaction. For an attractive self-interaction, we determine the maximum halo mass that can harbor a stable quantum core (dilute axion "star").