A new family of nonrelativistic, Newtonian, nonquantum equilibrium configurations describing galactic halos is introduced, by considering strange quark matter conglomerates with masses larger than about 8 GeV as new possible components of the dark matter. Originally introduced to explain the state of matter in neutron stars, such conglomerates may also form in the high density and temperature conditions of the primordial Universe and then decouple from ordinary baryonic matter, providing the fundamental components of dark matter for the formation of pristine gravitational potential wells and the subsequent evolution of cosmic structures. The obtained results for halomass and radius are consistent with the rotational velocity curve observed in the Galaxy. Additionally, the average density of such dark matter halos is similar to that derived for halos of dwarf spheroidal galaxies, which can therefore be interpreted as downscaled versions of larger dark matter distributions around Milky-Way-sized galaxies and hint for a common origin of the two families of cosmic structures.
Self-gravitating strange dark matter halos around galaxies / Merafina, Marco; Saturni, Francesco G.; Curceanu, Catalina; Del Grande, Raffaele; Piscicchia, Kristian. - In: PHYSICAL REVIEW D. - ISSN 2470-0010. - 102:8(2020), pp. 1-12. [10.1103/PhysRevD.102.083015]
Self-gravitating strange dark matter halos around galaxies
Merafina, Marco
Primo
;Saturni, Francesco G.;Piscicchia, Kristian
2020
Abstract
A new family of nonrelativistic, Newtonian, nonquantum equilibrium configurations describing galactic halos is introduced, by considering strange quark matter conglomerates with masses larger than about 8 GeV as new possible components of the dark matter. Originally introduced to explain the state of matter in neutron stars, such conglomerates may also form in the high density and temperature conditions of the primordial Universe and then decouple from ordinary baryonic matter, providing the fundamental components of dark matter for the formation of pristine gravitational potential wells and the subsequent evolution of cosmic structures. The obtained results for halomass and radius are consistent with the rotational velocity curve observed in the Galaxy. Additionally, the average density of such dark matter halos is similar to that derived for halos of dwarf spheroidal galaxies, which can therefore be interpreted as downscaled versions of larger dark matter distributions around Milky-Way-sized galaxies and hint for a common origin of the two families of cosmic structures.File | Dimensione | Formato | |
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