Theoretical dark matter halo density profile

Salvador-Solé, E.; Viñas, Jordi; Manrique, Alberto; Serra, Sinue

doi:10.1111/j.1365-2966.2012.21066.x

Cited by 33 publications

(36 citation statements)

References 69 publications

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“…Density profiles with this general form have been shown to arise even in the absence of hierarchical growth, for example from HDM initial conditions [134,135] or from sharply truncated initial power spectra [136]. The physical origin of this near-universal shape is not well understood, although many attempts at explanation have been put forward [137][138][139][140][141][142].…”

Section: −1mentioning

confidence: 99%

Dark matter and cosmic structure

2012

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The current standard model for the evolution of cosmic structure is reviewed, tracing its development over the last forty years and focussing specifically on the role played by numerical simulations and on aspects related to the nature of dark matter. PreambleThe development of a standard model of cosmological structure formation over the last forty years must count as one of the great success stories in Physics. The model describes the geometry and material content of the Universe, explaining how structure -galaxies of various sizes and types, groups and clusters of galaxies, the entire cosmic web of filaments and voids -emerged from a hot and near-uniform Big Bang. This astonishing richness appears to have grown from quantum zero-point fluctuations produced during a period of cosmic inflation occurring very soon after the beginning of our Universe. Over the subsequent 13.7 billion years, these small density perturbations were amplified by the relentless action of gravitational forces due predominantly to dark matter, but illuminated by complex astrophysical phenomena involving ordinary matter. In the standard model, the dark matter, which makes up five sixths of all matter, is hypothesised to be a weakly interacting non-baryonic elementary particle, created in the early stages of cosmic evolution.In this article we will review the standard model of cosmic structure formation, focusing on the nonlinear processes that transformed the near-uniform universe that emerged from the Big Bang into the highly structured world we observe today. We will highlight the critical role that computer simulations have played in understanding this transformation, emphasizing gravitational phenomena associated with the dark matter, and only rather briefly discussing the crucially important, but more complex, processes that shape the directly observable baryonic components. Rather than presenting a complete and thorough review of the literature, our intention is to provide an account of the main ideas and advances that have shaped the subject. We begin by presenting in Table 1 a chronological listing of the landmark developments that have driven this remarkable story.

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Section: −1mentioning

confidence: 99%

Dark matter and cosmic structure

2012

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“…The following slower accretion phase may be responsible for the outer slope of the density profile (Tasitsiomi et al 2004;Lu et al 2006;Hiotelis 2006). Halos would obtain the same, universal density profile independently of details about their collapse (El-Zant 2008;Wang & White 2009) and subsequent merger histories (Dehnen 2005;Kazantzidis et al 2006;El-Zant 2008;Wang & White 2009;Salvador-Solé et al 2012).…”

Section: Introductionmentioning

confidence: 99%

CLASH-VLT: The mass, velocity-anisotropy, and pseudo-phase-space density profiles of thez= 0.44 galaxy cluster MACS J1206.2-0847

Biviano

Rosati

Balestra

et al. 2013

A&A

159

174

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Aims. We constrain the mass, velocity-anisotropy, and pseudo-phase-space density profiles of the z = 0.44 CLASH cluster MACS J1206.2-0847, using the projected phase-space distribution of cluster galaxies in combination with gravitational lensing. Methods. We use an unprecedented data-set of 600 redshifts for cluster members, obtained as part of a VLT/VIMOS large program, to constrain the cluster mass profile over the radial range ∼0-5 Mpc (0-2.5 virial radii) using the MAMPOSSt and Caustic methods. We then add external constraints from our previous gravitational lensing analysis. We invert the Jeans equation to obtain the velocity-anisotropy profiles of cluster members. With the mass-density and velocity-anisotropy profiles we then obtain the first determination of a cluster pseudo-phase-space density profile. Results. The kinematics and lensing determinations of the cluster mass profile are in excellent agreement. This is very well fitted by a NFW model with mass M 200 = (1.4 ± 0.2) × 10 15 M and concentration c 200 = 6 ± 1, only slightly higher than theoretical expectations. Other mass profile models also provide acceptable fits to our data, of (slightly) lower (Burkert, Hernquist, and Softened Isothermal Sphere) or comparable (Einasto) quality than NFW. The velocity anisotropy profiles of the passive and star-forming cluster members are similar, close to isotropic near the center and increasingly radial outside. Passive cluster members follow extremely well the theoretical expectations for the pseudo-phase-space density profile and the relation between the slope of the mass-density profile and the velocity anisotropy. Star-forming cluster members show marginal deviations from theoretical expectations. Conclusions. This is the most accurate determination of a cluster mass profile out to a radius of 5 Mpc, and the only determination of the velocityanisotropy and pseudo-phase-space density profiles of both passive and star-forming galaxies for an individual cluster. These profiles provide constraints on the dynamical history of the cluster and its galaxies. Prospects for extending this analysis to a larger cluster sample are discussed.

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“…(3) a "virialization" model, put forward by Ref. [73], in which the final radius of a mass shell is determined by enforcing that the shell's enclosed energy be distributed according to the virial theorem.…”

Section: Density Profile At Large Radiimentioning

confidence: 99%

“…Reference [73] developed a model for halo density profiles in which a mass shell freezes where its enclosed energy is virialized. 17 In this model, the final radius of the q shell is r(q) = −(3/10)GM (q) 2 /E(q), where M (q) and E(q) are, respectively, the mass and energy enclosed within the q shell in the linear density field.…”

Section: Virializationmentioning

confidence: 99%

Predicting the density profiles of the first halos

2019

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The first dark matter halos form by direct collapse from peaks in the matter density field, and evidence from numerical simulations and other analyses suggests that the dense inner regions of these objects largely persist today. These halos would be the densest dark matter structures in the Universe, and their abundance can probe processes that leave imprints on the primordial density field, such as inflation or an early matter-dominated era. They can also probe dark matter through its free-streaming scale. The first halos are qualitatively different from halos that form by hierarchical clustering, as evidenced by their ρ ∝ r −3/2 inner density profiles. In this work, we present and tune models that predict the density profiles of these halos from properties of the density peaks from which they collapsed. These models predict the coefficient A of the ρ = Ar −3/2 small-radius asymptote of the density profile along with the maximum circular velocity vmax and associated radius rmax. These models are universal; they can be applied to any cosmology, and we confirm this by validating them using six N -body simulations carried out in wildly disparate cosmological scenarios. We find that these models can even predict the full population of halos with reasonable accuracy in scenarios with narrowly supported power spectra, although for broader power spectra, an understanding of the impact of halo mergers is needed. With their connection to the primordial density field established, the first dark matter halos will serve as probes of the early Universe and the nature of dark matter.

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Theoretical dark matter halo density profile

Cited by 33 publications

References 69 publications

Dark matter and cosmic structure

Dark matter and cosmic structure

CLASH-VLT: The mass, velocity-anisotropy, and pseudo-phase-space density profiles of thez= 0.44 galaxy cluster MACS J1206.2-0847

Predicting the density profiles of the first halos

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