FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1969264865> ?p ?o ?g. }

• W1969264865 endingPage "542" @default.
• W1969264865 startingPage "528" @default.
• W1969264865 abstract "During hierarchical clustering, smaller masses generally collapse earlier than larger masses and so are denser on the average. The core of a small-mass halo could be dense enough to resist disruption and survive undigested when it is incorporated into a larger object. We explore the possibility that a nested sequence of undigested cores in the center of the halo that have survived the hierarchical, inhomogeneous collapse to form larger and larger objects determines the halo structure in the inner regions. For a flat universe with P(k) ∝ kn, scaling arguments then suggest that the core density profile is ρ ∝ r-α, with α = (9 + 3n)/(5 + n). For any n < 1, the signature of undigested cores is a core density profile shallower than ρ ∝ 1/r2 and dependent on the power spectrum. For typical objects formed from a cold dark matter (CDM)-like power spectrum, the effective value of n is close to -2, and thus α could typically be near 1, the Navarro, Frenk, & White (NFW) value. Velocity dispersions should also decrease with decreasing radius within the core. However, whether such behavior holds depends on detailed dynamics. We first examine the dynamics using a fluid approach to the self-similar collapse solutions for the dark matter phase-space density, including the effect of velocity dispersions. We highlight the importance of tangential velocity dispersions to obtain density profiles shallower than 1/r2 in the core regions. If tangential velocity dispersions in the core are constrained to be less than the radial dispersion, a cuspy core density profile shallower than 1/r cannot hold in self-similar collapse. We then look at the profiles of the outer halos in low-density cosmological models in which the total halo mass is convergent. We find a limiting r-4 outer profile for the open case and a limiting outer profile for the Λ-dominated case, which approaches the form [1 - (r/λ)-3]1/2, where 3 is the logarithmic slope of the initial density profile. Finally, we analyze a suite of dark halo density and velocity dispersion profiles obtained in cosmological N-body simulations of models with n = 0, -1, and -2. The core-density profiles show considerable scatter in their properties, but nevertheless do appear to reflect a memory of the initial power spectrum, with steeper initial spectra producing flatter core profiles. These results apply as well for low-density cosmological models (Ωmatter = 0.2-0.3), since high-density cores were formed early, where Ωmatter ≈ 1." @default.
• W1969264865 created "2016-06-24" @default.
• W1969264865 creator A5019025722 @default.
• W1969264865 creator A5041494907 @default.
• W1969264865 creator A5045925716 @default.
• W1969264865 date "2000-08-01" @default.
• W1969264865 modified "2023-10-16" @default.
• W1969264865 title "The Structure of Dark Matter Halos in Hierarchical Clustering Theories" @default.
• W1969264865 cites W1978498913 @default.
• W1969264865 cites W1982445375 @default.
• W1969264865 cites W1983113556 @default.
• W1969264865 cites W1991334838 @default.
• W1969264865 cites W1999244535 @default.
• W1969264865 cites W2007364459 @default.
• W1969264865 cites W2008084436 @default.
• W1969264865 cites W2012119171 @default.
• W1969264865 cites W2013306300 @default.
• W1969264865 cites W2014961159 @default.
• W1969264865 cites W2015222486 @default.
• W1969264865 cites W2020827391 @default.
• W1969264865 cites W2020868196 @default.
• W1969264865 cites W2025603133 @default.
• W1969264865 cites W2027366375 @default.
• W1969264865 cites W2031069403 @default.
• W1969264865 cites W2031884433 @default.
• W1969264865 cites W2033592163 @default.
• W1969264865 cites W2040994759 @default.
• W1969264865 cites W2042863027 @default.
• W1969264865 cites W2049737266 @default.
• W1969264865 cites W2051694884 @default.
• W1969264865 cites W2065980009 @default.
• W1969264865 cites W2070998352 @default.
• W1969264865 cites W2072235278 @default.
• W1969264865 cites W2075280515 @default.
• W1969264865 cites W2080871773 @default.
• W1969264865 cites W2101064800 @default.
• W1969264865 cites W2104572967 @default.
• W1969264865 cites W2125429969 @default.
• W1969264865 cites W2136827143 @default.
• W1969264865 cites W2153401290 @default.
• W1969264865 cites W2161641687 @default.
• W1969264865 cites W2162290847 @default.
• W1969264865 cites W2165291644 @default.
• W1969264865 cites W3099049211 @default.
• W1969264865 cites W3100110286 @default.
• W1969264865 cites W3100882820 @default.
• W1969264865 cites W3103877238 @default.
• W1969264865 cites W3104146119 @default.
• W1969264865 cites W4292930832 @default.
• W1969264865 doi "https://doi.org/10.1086/309152" @default.
• W1969264865 hasPublicationYear "2000" @default.
• W1969264865 type Work @default.
• W1969264865 sameAs 1969264865 @default.
• W1969264865 citedByCount "116" @default.
• W1969264865 countsByYear W19692648652012 @default.
• W1969264865 countsByYear W19692648652013 @default.
• W1969264865 countsByYear W19692648652014 @default.
• W1969264865 countsByYear W19692648652015 @default.
• W1969264865 countsByYear W19692648652016 @default.
• W1969264865 countsByYear W19692648652017 @default.
• W1969264865 countsByYear W19692648652018 @default.
• W1969264865 countsByYear W19692648652019 @default.
• W1969264865 countsByYear W19692648652020 @default.
• W1969264865 countsByYear W19692648652021 @default.
• W1969264865 countsByYear W19692648652022 @default.
• W1969264865 crossrefType "journal-article" @default.
• W1969264865 hasAuthorship W1969264865A5019025722 @default.
• W1969264865 hasAuthorship W1969264865A5041494907 @default.
• W1969264865 hasAuthorship W1969264865A5045925716 @default.
• W1969264865 hasBestOaLocation W19692648651 @default.
• W1969264865 hasConcept C120665830 @default.
• W1969264865 hasConcept C121332964 @default.
• W1969264865 hasConcept C126320844 @default.
• W1969264865 hasConcept C127529279 @default.
• W1969264865 hasConcept C159249277 @default.
• W1969264865 hasConcept C178635117 @default.
• W1969264865 hasConcept C184665706 @default.
• W1969264865 hasConcept C2164484 @default.
• W1969264865 hasConcept C38652104 @default.
• W1969264865 hasConcept C41008148 @default.
• W1969264865 hasConcept C44870925 @default.
• W1969264865 hasConcept C51650839 @default.
• W1969264865 hasConcept C72782756 @default.
• W1969264865 hasConcept C8058405 @default.
• W1969264865 hasConcept C88148261 @default.
• W1969264865 hasConcept C98444146 @default.
• W1969264865 hasConceptScore W1969264865C120665830 @default.
• W1969264865 hasConceptScore W1969264865C121332964 @default.
• W1969264865 hasConceptScore W1969264865C126320844 @default.
• W1969264865 hasConceptScore W1969264865C127529279 @default.
• W1969264865 hasConceptScore W1969264865C159249277 @default.
• W1969264865 hasConceptScore W1969264865C178635117 @default.
• W1969264865 hasConceptScore W1969264865C184665706 @default.
• W1969264865 hasConceptScore W1969264865C2164484 @default.
• W1969264865 hasConceptScore W1969264865C38652104 @default.
• W1969264865 hasConceptScore W1969264865C41008148 @default.
• W1969264865 hasConceptScore W1969264865C44870925 @default.
• W1969264865 hasConceptScore W1969264865C51650839 @default.

• next