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The Galactic Halo in Mixed Dark Matter Cosmologies

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arxiv 1206.3788 v3 pith:RQSJDYMZ submitted 2012-06-17 astro-ph.CO astro-ph.GA

The Galactic Halo in Mixed Dark Matter Cosmologies

classification astro-ph.CO astro-ph.GA
keywords darkmattercomponentansatzcoldfractionhalolocal
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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A possible solution to the small scale problems of the cold dark matter (CDM) scenario is that the dark matter consists of two components, a cold and a warm one. We perform a set of high resolution simulations of the Milky Way halo varying the mass of the WDM particle ($m_{\rm WDM}$) and the cosmic dark matter mass fraction in the WDM component ($\bar{f}_{\rm W}$). The scaling ansatz introduced in combined analysis of LHC and astroparticle searches postulates that the relative contribution of each dark matter component is the same locally as on average in the Universe (e.g. $f_{\rm W,\odot} = \bar{f}_{\rm W}$). Here we find however, that the normalised local WDM fraction ($f_{\rm W,\odot}$ / $\bar{f}_{\rm W}$) depends strongly on $m_{\rm WDM}$ for $m_{\rm WDM} <$ 1 keV. Using the scaling ansatz can therefore introduce significant errors into the interpretation of dark matter searches. To correct this issue a simple formula that fits the local dark matter densities of each component is provided.

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Cited by 2 Pith papers

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  1. Holographic dark energy as a source for slowly rotating wormholes: Implications for null geodesics and shadows

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    Slowly rotating wormholes in Rényi, mixed, and Moradpour holographic dark energy produce distinct photon orbits and shadow morphologies, with Rényi models yielding smaller asymmetric shadows.

  2. Halo mass functions in mixed cold and fuzzy dark matter models

    astro-ph.CO 2026-06 unverdicted novelty 5.0

    Simulations show fuzzy dark matter fraction up to 0.3 suppresses low-mass halos in mixed DM models, and a redshift- and fraction-dependent suppression function maps CDM HMFs to MDM HMFs within 0.1-0.2 dex accuracy for z=1-4.