2015
DOI: 10.1103/physrevd.91.083501
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Anisotropy of the extragalactic radio background from dark matter annihilation

Abstract: Observations of the extragalactic radio background have uncovered a significant isotropic emission across multiple frequencies spanning from 22 MHz to 10 GHz. The intensity of this non-thermal emission component significantly exceeds the expected contribution from known astrophysical sources. Interestingly, models have indicated that the annihilation of dark matter particles may reproduce both the flux and spectrum of the excess. However, the lack of a measurable anisotropy in the residual emission remains cha… Show more

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Cited by 10 publications
(11 citation statements)
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References 71 publications
(149 reference statements)
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“…Dark matter models are well motivated for explanations of ARCADE-2 since they naturally produce large fluxes of relativistic e + e − while producing negligible thermal emission. This allows dark matter induced emission to simultaneously fit the intensity of the ARCADE-2 excess while remaining consistent with infrared constraints, and several similar models have been formulated to date [11][12][13][14].…”
Section: Introductionmentioning
confidence: 78%
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“…Dark matter models are well motivated for explanations of ARCADE-2 since they naturally produce large fluxes of relativistic e + e − while producing negligible thermal emission. This allows dark matter induced emission to simultaneously fit the intensity of the ARCADE-2 excess while remaining consistent with infrared constraints, and several similar models have been formulated to date [11][12][13][14].…”
Section: Introductionmentioning
confidence: 78%
“…where η ∼ 3/8 [14], and B 0 is the central magnetic field strength of clusters. We leave B 0 as our first adjustable parameter with a default value B 0 = 10µG.…”
Section: Density Profile Magnetic Field and Temperature Of A Clustermentioning
confidence: 99%
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“…A flatter spectrum can be obtained by hardening the electron injection in some energy range, such as having electron secondaries produced through hadronic interactions A possible solution would be a model where local magnetic field enhancements trace cluster dark matter substructure, even far away from cluster centers. As investigated in Fang & Linden (2015), in such regions of locally enhanced magnetic field, the magnetic field turbulence can give rise to Alfvén waves, which re-accelerate the electrons, leading to a locally enhanced synchtrotron emissivity. Since the synchrotron emission would be happening only in these localized regions of the energetic electrons and enhanced magnetic fields, the overall inverse-Compton emission level for a given amount of synchrotron could be suppressed.…”
Section: Diffuse Extragalactic Syncrotron Emission and Thementioning
confidence: 99%
“…A number of potential particle-related explanations for RSB emission mechanisms have been suggested, including intergalactic dark matter decays and annihilations in halos and filaments (e.g. [24,25,26]), ultracompact halos [27], or in the relatively early Universe (e.g. [28]), "dark stars" in the early universe [29], supernovae of massive population III (first generation) stars [30], and dense nuggets of quarks [31].…”
Section: Hypothesized Source Classesmentioning
confidence: 99%