Abstract
Dark matter could have a dissipative asymmetric subcomponent in the form of atomic dark matter (aDM). This arises in many scenarios of dark complexity, and is a prediction of neutral naturalness, such as the Mirror Twin Higgs model. We show for the first time how White Dwarf cooling provides strong bounds on aDM. In the presence of a small kinetic mixing between the dark and SM photon, stars are expected to accumulate atomic dark matter in their cores, which then radiates away energy in the form of dark photons. In the case of white dwarfs, this energy loss can have a detectable impact on their cooling rate. We use measurements of the white dwarf luminosity function to tightly constrain the kinetic mixing parameter between the dark and visible photons, for DM masses in the range 10−5–105 GeV, down to values of ϵ ∼ 10−12. Using this method we can constrain scenarios in which aDM constitutes fractions as small as 10−3 of the total dark matter density. Our methods are highly complementary to other methods of probing aDM, especially in scenarios where the aDM is arranged in a dark disk, which can make direct detection extremely difficult but actually slightly enhances our cooling constraints.
Highlights
As high as 5-10% are much more difficult to rule out
We present the numerical results of our study, outlining the deviations in white dwarf cooling behavior we predict for atomic dark matter (aDM), and presenting bounds on aDM parameter space from the WDLF
As figure 1 demonstrates, this means our bounds could be improved by a factor of at least a few by performing a more careful fit to the WDLF
Summary
The high density of white dwarfs leads to a suppression of the aDM evaporation rate (see section 4.2), especially for small dark matter masses This effect of the dark photon energy loss becomes more pronounced as the white dwarf ages and gets colder. Since the best observational data comes from relatively nearby white dwarfs (within a few hundred pc), we are effectively probing the local dark matter density (on galactic scales) These are the same observables probed by direct detection experiments, and we are highly complimentary to existing/upcoming constraints. We find that white dwarf cooling provides the strongest existing constraints to date on direct detection of many aDM scenarios in general, and asymetrically reheated Mirror Twin Higgs models in particular (see [65])
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