Observationally inferred dark matter phase-space distribution and direct detection experiments

Mandal, Sayan; Majumdar, Subhabrata; Rentala, Vikram; Thakur, R. Basu

doi:10.1103/physrevd.100.023002

Cited by 9 publications

(8 citation statements)

References 74 publications

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“…The number of terms in the sum is equal to the number of unique ways of partitioning q into any number of smaller terms, i.e., the partition function of q. The first ten partitions are 1,2,3,5,7,11,15,22,30 and 42, and, asymptotically, the number of partitions grows exponentially with q. The formula allows us to express complicated moments of a multinomial in terms of simpler ones; in this regard, it is similar to Wick's theorem for Gaussian moments.…”

Section: A Averaged Poisson Likelihoodmentioning

confidence: 99%

Non-parametric uncertainties in the dark matter velocity distribution

Fowlie

2019

J. Cosmol. Astropart. Phys.

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We investigate the impact of uncertainty in the velocity distribution of dark matter on direct detection experiments. We construct an multinomial prior with a hyperparameter β that describes the strength of our belief in an isotropic Maxwell-Boltzmann velocity distribution. By varying β, we interpolate between a halo-independent and halo-dependent analysis. We present a novel approximation for the marginalisation of this prior that is applicable to any counting experiment. With this formula, we investigate the impact of the uncertainty in limits from XENON1T. For dark matter masses greater than about 60 GeV, we find extremely mild sensitivity to the distribution. Below about 60 GeV, the limit weakens by less than an order of magnitude if we assume an isotropic distribution in the galactic frame. If we permit anisotropic distributions, the limit further weakens, but at most by about two orders of magnitude. Lastly, we check the impact of parametric uncertainties and discuss the possible inclusion and impact of our technique in global fits.

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Section: A Averaged Poisson Likelihoodmentioning

confidence: 99%

Non-parametric uncertainties in the dark matter velocity distribution

Fowlie

2019

J. Cosmol. Astropart. Phys.

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“…One possibility is to use the motion of stars to constrain the local gravitational potential (or density) and to subsequently infer the velocity distribution using the Jeans theorem. A variety of proposals of this nature have been made (Hansen & Moore 2006;Chaudhury et al 2010;Lisanti et al 2011;Catena & Ullio 2012;Bhattacharjee et al 2013;Bozorgnia et al 2013;Fornasa & Green 2014;Mandal et al 2018), but they typically rely on the assumption that the DM is isotropic and/or in equilibrium, either of which may be violated depending on the Milky Way's accretion history.…”

Section: Introductionmentioning

confidence: 99%

Inferred Evidence for Dark Matter Kinematic Substructure with SDSS–Gaia

Necib

Lisanti

Belokurov

2019

ApJ

126

137

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We use the distribution of accreted stars in Sloan Digital Sky Survey-Gaia DR2 to demonstrate that a nontrivial fraction of the dark matter halo within galactocentric radii of 7.5-10 kpc and > | | z 2.5 kpc is in substructure and thus may not be in equilibrium. Using a mixture likelihood analysis, we separate the contributions of an old, isotropic stellar halo and a younger anisotropic population. The latter dominates and is uniform within the region studied. It can be explained as the tidal debris of a disrupted massive satellite on a highly radial orbit and is consistent with mounting evidence from recent studies. Simulations that track the tidal debris from such mergers find that the dark matter traces the kinematics of its stellar counterpart. If so, our results indicate that a component of the nearby dark matter halo that is sourced by luminous satellites is in kinematic substructure referred to as debris flow. These results challenge the Standard Halo Model, which is discrepant with the distribution recovered from the stellar data, and have important ramifications for the interpretation of direct detection experiments.

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“…[34]). Deviations from this simple model of the DM halo are expected in the Milky Way [35][36][37][38] and while the parameters associated with the SHM (such as the Sun's velocity [39], the local circular velocity [40] and the Galactic escape velocity [41]) can be estimated observationally, they carry with them an associated uncertainty [10,42,43]. In addition, numerical simulations have suggested the possibility of non-Maxwellian structure in the DM velocity distribution [44][45][46][47][48][49][50][51].…”

Section: Introductionmentioning

confidence: 99%

Bracketing the impact of astrophysical uncertainties on local dark matter searches

Ibarra

Kavanagh

Rappelt

2018

J. Cosmol. Astropart. Phys.

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The theoretical interpretation of dark matter (DM) experiments is hindered by uncertainties on the dark matter density and velocity distribution inside the Solar System. In order to quantify those uncertainties, we present a parameter that characterizes the deviation of the true velocity distribution from the standard Maxwell-Boltzmann form, and we then determine for different values of this parameter the most aggressive and most conservative limits on the dark matter scattering cross section with nuclei; uncertainties in the local dark matter density can be accounted for trivially. This allows us to bracket, in a model independent way, the impact of astrophysical uncertainties on limits from direct detection experiments and/or neutrino telescopes. We find that current limits assuming the Standard Halo Model are at most a factor of ∼ 2 weaker than the most aggressive possible constraints. In addition, combining neutrino telescope and direct detection constraints (in a statistically meaningful way), we show that limits on DM in the mass range ∼ 10 − 1000 GeV cannot be weakened by more than around a factor of 10, for all possible velocity distributions. We finally demonstrate that our approach can also be employed in the event of a DM discovery, allowing us to avoid bias in the reconstruction of the DM properties.

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Observationally inferred dark matter phase-space distribution and direct detection experiments

Cited by 9 publications

References 74 publications

Non-parametric uncertainties in the dark matter velocity distribution

Non-parametric uncertainties in the dark matter velocity distribution

Inferred Evidence for Dark Matter Kinematic Substructure with SDSS–Gaia

Bracketing the impact of astrophysical uncertainties on local dark matter searches

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