Fluctuations of the gravitational field generated by a random population of extended substructures

Peñarrubia, Jorge

doi:10.1093/mnras/stx2773

Cited by 22 publications

(26 citation statements)

References 83 publications

(125 reference statements)

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“…The other simulation denoted B N4096L400 ignored the effect of the free motion. The cosmological parameters are Ω 0 = 0.31, λ 0 = 0.69, h = 0.68, n s = 0.96, and σ 8 = 0.83, which are consistent with an observation of the cosmic microwave background obtained by the Planck satellite (Planck Collaboration et al 2014, 2016, 2018. The initial conditions were generated by a first-order Zeldovich approximation at z = 400.…”

Section: Initial Conditions and Numerical Methodssupporting

confidence: 69%

“…Such steep cusps may have a significant effect on dark matter searches. There are a variety of subjects such as gravitational lensing (Chen & Koushiappas 2010;Erickcek & Law 2011;Van Tilburg et al 2018), Gravitational Waves (Bird et al 2016), Galactic tidal fluctuations (Peñarrubia 2018), gravitational perturbations on the Solar system (González-Morales et al 2013), pulsar timing arrays (Ishiyama et al 2010;Baghram et al 2011;Kashiyama & Oguri 2018) and indirect detection experiments (e.g., Berezinsky et al 2003;Koushiappas et al 2004;Koushiappas 2006;Goerdt et al 2007;Diemand et al 2007;Ando et al 2008;Ishiyama 2014;Bartels & Ando 2015;Fornasa & Sánchez-Conde 2015;Anderson et al 2016;Marchegiani & Colafrancesco 2016;Hütten et al 2016Hütten et al , 2018Hooper & Witte 2017;Moliné et al 2017;Stref & Lavalle 2017;Hiroshima et al 2018;Kamada et al 2019, and see also a recent review by Ando et al 2019). I14 showed that the steeper inner cusps of haloes near the free streaming scale can increase the dark matter annihilation luminosity of a Milky-Way sized halo between 12 % to 67 %, compared with the case we assume the NFW density profile (Navarro et al 1997) and an empirical mass-concentration relation proposed by Sánchez-Conde & Prada (2014).…”

Section: Introductionmentioning

confidence: 99%

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The abundance and structure of subhaloes near the free streaming scale and their impact on indirect dark matter searches

Ishiyama

Ando

2020

Monthly Notices of the Royal Astronomical Society

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The free streaming motion of dark matter particles imprints a cutoff in the matter power spectrum and set the scale of the smallest dark matter halo. Recent cosmological N-body simulations have shown that the central density cusp is much steeper in haloes near the free streaming scale than in more massive haloes. Here, we study the abundance and structure of subhaloes near the free streaming scale at very high redshift using a suite of unprecedentedly large cosmological N-body simulations, over a wide range of the host halo mass. The subhalo abundance is suppressed strongly below the free streaming scale, but the ratio between the subhalo mass function in the cutoff and no cutoff simulations is well fitted by a single correction function regardless of the host halo mass and the redshift. In subhaloes, the central slopes are considerably shallower than in field haloes, however, are still steeper than that of the NFW profile. Contrary, the concentrations are significantly larger in subhaloes than haloes and depend on the subhalo mass. We compare two methods to extrapolate the mass-concentration relation of haloes and subhaloes to z=0 and provide a new simple fitting function for subhaloes, based on a suite of large cosmological N-body simulations. Finally, we estimate the annihilation boost factor of a Milky-Way sized halo to be between 1.8 and 6.2.

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Section: Initial Conditions and Numerical Methodssupporting

confidence: 69%

Section: Introductionmentioning

confidence: 99%

The abundance and structure of subhaloes near the free streaming scale and their impact on indirect dark matter searches

Ishiyama

Ando

2020

Monthly Notices of the Royal Astronomical Society

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“…Summarising, the super-cool contribution dominates provided that T RH T dec . If DM interaction are small enough that it does not undergo kinetic recoupling, DM remains colder than in the freeze-out scenario: this has little observational implications [19]; the fact that supercool DM forms smaller structures could give enhanced tidal fluctuations possibly observable along the lines of [20]. The super-cool population of eq.…”

Section: Reheatingmentioning

confidence: 97%

Super-cool Dark Matter

Hambye

Струмиа

Teresi

2018

J. High Energ. Phys.

108

126

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In dimension-less theories of dynamical generation of the weak scale, the Universe can undergo a period of low-scale inflation during which all particles are massless and undergo super-cooling. This leads to a new mechanism of generation of the cosmological Dark Matter relic density: super-cooling can easily suppress the amount of Dark Matter down to the desired level. This is achieved for TeV-scale Dark Matter, if super-cooling ends when quark condensates form at the QCD phase transition. Along this scenario, the baryon asymmetry can be generated either at the phase transition or through leptogenesis. We show that the above mechanism takes place in old and new dimension-less models.

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“…Therefore, a ruling on the existence of low-mass ( 10 7 M ) dark matter subhalos would place strong constraints on the nature of dark matter (e.g., Bullock & Boylan-Kolchin 2017;Buckley & Peter 2017), which can be fur-arXiv:1811.03631v2 [astro-ph.GA] 13 Jun 2019 ther refined by measuring the minimum halo mass (e.g., Schmid et al 1999;Hofmann et al 2001;Loeb & Zaldarriaga 2005). Albeit dark, low-mass subhalos should still exert gravitational influence, for example, fluctuations of the gravitational tidal field are sensitive to the presence of subhalos down to 10 −6 M (Peñarrubia 2018). In a cosmological volume, however, gravitational lensing is our most sensitive method of detecting gravitational perturbations.…”

Section: Introductionmentioning

confidence: 99%

The Spur and the Gap in GD-1: Dynamical Evidence for a Dark Substructure in the Milky Way Halo

Bonaca

Hogg

Price-Whelan

et al. 2019

ApJ

196

181

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We present a model for the interaction of the GD-1 stellar stream with a massive perturber that naturally explains many of the observed stream features, including a gap and an off-stream spur of stars. The model involves an impulse by a fast encounter, after which the stream grows a loop of stars at different orbital energies. At specific viewing angles, this loop appears offset from the stream track. A quantitative comparison of the spur and gap features prefers models where the perturber is in the mass range of 10 6 M to 10 8 M . Orbit integrations back in time show that the stream encounter could not have been caused by any known globular cluster or dwarf galaxy with a determined orbit, and mass, size and impact-parameter arguments show that it could not have been caused by a molecular cloud in the Milky Way disk. The most plausible explanation for the gap-and-spur structure is an encounter with a dark-matter substructure, like those predicted to populate galactic halos in ΛCDM cosmology. However, the expected densities of ΛCDM subhalos in this mass range and in this part of the Milky Way are 2 − 3 σ lower than the inferred density of the GD-1 perturber. This observation opens up the possibility that detailed observations of streams could measure the mass spectrum of dark-matter substructures and even identify individual substructures and their orbits in the Galactic halo.

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Fluctuations of the gravitational field generated by a random population of extended substructures

Cited by 22 publications

References 83 publications

The abundance and structure of subhaloes near the free streaming scale and their impact on indirect dark matter searches

The abundance and structure of subhaloes near the free streaming scale and their impact on indirect dark matter searches

Super-cool Dark Matter

The Spur and the Gap in GD-1: Dynamical Evidence for a Dark Substructure in the Milky Way Halo

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