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Wave dark matter and ultra-diffuse galaxies

Alvaro Pozo, Tom Broadhurst, Ivan De Martino, Hoang Nhan Luu, George F. Smoot, Jeremy Lim, Mark C. Neyrinck

2021Monthly Notices of the Royal Astronomical Society24 citationsDOIOpen Access PDF

Abstract

ABSTRACT Dark matter (DM) as a Bose–Einstein condensate, such as the axionic scalar field particles of String Theory, can explain the coldness of DM on large scales. Pioneering simulations in this context predict a rich wave-like structure, with a ground state soliton core in every galaxy surrounded by a halo of excited states that interfere on the de Broglie scale. This de Broglie scale is largest for the low-mass galaxies as momentum is lower, providing a simple explanation for the wide cores of dwarf spheroidal galaxies. Here we extend these ‘wave dark matter’ (ψDM) predictions to the newly discovered class of ‘ultra-diffuse galaxies’ (UDG) that resemble dwarf spheroidal galaxies but with more extended stellar profiles. Currently, the best-studied example, ‘Dragon Fly 44’ (DF44), has a uniform velocity dispersion of ≃33 km s−1, extending to at least 3 kpc, that we show is reproduced by our ψDM simulations with a soliton radius of ≃0.5 kpc. In the ψDM context, we show that relatively flat dispersion profile of DF44 lies between massive galaxies with compact dense solitons, as may be present in the Milky Way on a scale of 100 pc and lower mass galaxies where the velocity dispersion declines centrally within a wide, low-density soliton, like Antlia II, of radius 3 kpc.

Topics & Concepts

PhysicsDark matterAstrophysicsGalaxyAstronomyDark Matter and Cosmic PhenomenaScientific Research and DiscoveriesGalaxies: Formation, Evolution, Phenomena
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