Effective 
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-factor of the Galactic Center for velocity-dependent dark matter annihilation

Boddy, Kimberly K.; Kumar, Jason; Strigari, Louis E.

doi:10.1103/physrevd.98.063012

Cited by 42 publications

(28 citation statements)

References 68 publications

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“…For the larger values of n, the scale free angular distribution is increasingly suppressed at both large and smallθ. This finding is consistent with previous results studying the angular distribution of gamma-ray emission from dark matter annihilation in the Milky Way halo [17]. The suppression arises because dark matter particle velocities tend to be suppressed both close to and far from the subhalo center.…”

Section: B Application To An Nfw Profilesupporting

confidence: 93%

“…There has been recent renewed interest in extending these limits by examining the effects of velocitydependent dark matter annihilation on the flux of gamma rays emitted by astrophysical objects with high dark matter densities [11][12][13][14][15][16][17][18]. In particular, for velocitydependent annihilation, the standard factorization of the gamma-ray flux into an astrophysical contribution (the J-factor) and a particle physics contribution fails, because the dark matter annihilation cross section is nontrivially correlated with the dark matter velocity distribution.…”

Section: Introductionmentioning

confidence: 99%

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Angular distribution of gamma-ray emission from velocity-dependent dark matter annihilation in subhalos

et al. 2019

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We consider the effect of velocity-dependent dark matter annihilation on the angular distribution of gamma rays produced in dark matter subhalos. We assume that the dark matter potential is spherically symmetric, characterized by a scale radius and scale density, and the velocity distribution is isotropic. We find that the effect of velocity-dependent dark matter annihilation is largely determined by dimensional analysis; the angular size of gamma-ray emission from an individual subhalo is rescaled by a factor which depends on the form of the dark matter distribution, but not on the halo parameters, while the relative normalization of the gamma-ray flux from different mass subhalos is rescaled by a factor which depends on the halo parameters, but not on the form of the dark matter distribution. We apply our results to a Navarro-Frenk-White profile for the case of an individual subhalo and comment on the application of these results to a distribution of subhalos.

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Section: B Application To An Nfw Profilesupporting

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Angular distribution of gamma-ray emission from velocity-dependent dark matter annihilation in subhalos

et al. 2019

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“…The approach taken by [4][5][6] as well as in CMB studies of DM-hydrogen interaction [13,14,26,27] is a modelindependent one, where one assumes the above velocity dependence in the cross section without specifying its origin. In light of recent advancements it is natural to ask whether there exists a particle physics model that can address the EDGES observation while being consistent with the existing limits.…”

Section: Introductionmentioning

confidence: 99%

Strong constraints on light dark matter interpretation of the EDGES signal

et al. 2018

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Recently the EDGES collaboration reported an anomalous absorption signal in the sky-averaged 21-cm spectrum around z ¼ 17. Such a signal may be understood as an indication for an unexpected cooling of the hydrogen gas during or prior to the so-called Cosmic Dawn era. Here we explore the possibility that sub GeV dark matter cooled the gas through velocity-dependent, Rutherford-like interactions. We argue that such interactions require a light mediator that is highly constrained by 5th force experiments and limits from stellar cooling. Consequently, only a hidden or the visible photon can in principle mediate such a force. Neutral hydrogen thus plays a subleading role and the cooling occurs via the residual free electrons and protons. We find that these two scenarios are strongly constrained by the predicted dark matter selfinteractions and by limits on millicharged dark matter, respectively. We conclude that the 21-cm absorption line is unlikely to be the result of gas cooling via the scattering with a dominant component of the dark matter. An order 1% subcomponent of millicharged dark matter remains a viable explanation.

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“…For instance, the annihilation cross-section could depend on the relative DM velocity, which varies between astrophysical systems. In such a case, however, an effective factorization can still be achieved and so the discussion of this sections ports over directly, although the velocity dependence of the cross-section is now placed into the astrophysics factor, see e.g [89]…”

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confidence: 99%

Dark matter spectra from the electroweak to the Planck scale

Bauer

Rodd

Webber

2021

J. High Energ. Phys.

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We compute the decay spectrum for dark matter (DM) with masses above the scale of electroweak symmetry breaking, all the way to the Planck scale. For an arbitrary hard process involving a decay to the unbroken standard model, we determine the prompt distribution of stable states including photons, neutrinos, positrons, and antiprotons. These spectra are a crucial ingredient in the search for DM via indirect detection at the highest energies as being probed in current and upcoming experiments including IceCube, HAWC, CTA, and LHAASO. Our approach improves considerably on existing methods, for instance, we include all relevant electroweak interactions.

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Effective J -factor of the Galactic Center for velocity-dependent dark matter annihilation

Cited by 42 publications

References 68 publications

Angular distribution of gamma-ray emission from velocity-dependent dark matter annihilation in subhalos

Angular distribution of gamma-ray emission from velocity-dependent dark matter annihilation in subhalos

Strong constraints on light dark matter interpretation of the EDGES signal

Dark matter spectra from the electroweak to the Planck scale

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