1 / 45

The Halo Model

The Halo Model. Structure formation: cosmic capitalism Halos: abundances, clustering and evolution Galaxies: a nonlinear biased view of dark matters Marked correlations: There’s more to the points Ravi K. Sheth (UPitt/UPenn). Galaxy Surveys. Galaxy clustering depends on type.

hilel-ramsey
Download Presentation

The Halo Model

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. The Halo Model • Structure formation: cosmic capitalism • Halos: abundances, clustering and evolution • Galaxies: a nonlinear biased view of dark matters • Marked correlations: There’s more to the points Ravi K. Sheth (UPitt/UPenn)

  2. Galaxy Surveys

  3. Galaxy clustering depends on type Large samples now available to quantify this

  4. Light is a biased tracer To use galaxies as probes of underlying dark matter distribution, must understand ‘bias’

  5. Center-satellite process requires knowledge of • halo abundance; 2) halo clustering; 3) halo profiles; • 4) how number of galaxies per halo depends on halo mass. • (Also a simple model of earthquakes and aftershocks!)

  6. Neyman & Scott • Hypothesis testing (J. Neyman) • Model of ozone • Model of cancer • Model of BCGs (E. Scott) • Clustering model (Neyman & Scott)

  7. The halo-model of clustering • Two types of pairs: both particles in same halo, or particles in different halos • ξdm(r) =ξ1h(r) + ξ2h(r) • All physics can be decomposed similarly: influences from within halo, versus from outside (Sheth 1996)

  8. Gaussian fluctuations as seeds of subsequent structure formation Gaussianity simplifies mathematics: logic which follows is general

  9. N-body simulations of gravitational clustering in an expanding universe

  10. Cold Dark Matter • Simulations include gravity only (no gas) • Late-time field retains memory of initial conditions • Cosmic capitalism Co-moving volume ~ 100 Mpc/h

  11. It’s a capitalist’s life… • Most of the action is in the big cities • Newcomers to the city are rapidly stripped of (almost!) all they have • Encounters generally too high-speed to lead to long-lasting mergers • Repeated ‘harassment’ can lead to change • Real interactions take place in the outskirts • A network exists to channel resources from the fields to feed the cities

  12. Spherical evolution model • ‘Collapse’ depends on initial over-density Di; same for all initial sizes • Critical density depends on cosmology • Final objects all have same density, whatever their initial sizes • Collapsed objects called halos; • ~ 200× denser than background, whatever their mass (Tormen 1998) (Figure shows particles at z~2 which, at z~0, are in a cluster)

  13. Spherical evolution model • Initially, Ei = – GM/Ri + (HiRi)2/2 • Shells remain concentric as object evolves; if denser than background, object pulls itself together as background expands around it • At ‘turnaround’: E = – GM/rmax = Ei • So – GM/rmax = – GM/Ri + (HiRi)2/2 • Hence (Ri/rmax) = 1 – Hi2Ri3/2GM = 1 – (3Hi2 /8pG) (4pRi3/3)/M = 1 – 1/(1+Di) = Di/(1+Di)≈ Di

  14. Virialization • Final object virializes: −W = 2K • Evir = W+K = W/2 = −GM/2rvir= −GM/rmax • So rvir = rmax/2: final size, density of object determined by initial overdensity • To form an object at present time, must have had a critical overdensity initially • To form objects at high redshift, must have been even more overdense initially • At any given time, all objects have same density (high-z objects denser)

  15. Virial Motions • (Ri/rvir) ~ f(Di): ratio of initial and final sizes depends on initial overdensity • Mass M ~ (1+Di)Ri3~ Ri3 (since initial overdensity « 1) • So final virial density ~ M/rvir3 ~ (Ri/rvir)3 ~ function of critical density: hence, at any given time, all virialized objects have the same density, whatever their mass • V2 ~ GM/rvir ~ M2/3: massive objects have larger internal velocities/temperatures

  16. Spherical evolution model • ‘Collapse’ depends on initial over-density Di; same for all initial sizes • Critical density depends on cosmology • Final objects all have same density, whatever their initial sizes • Collapsed objects called halos; • ~ 200× denser than background, whatever their mass (Tormen 1998) (Figure shows particles at z~2 which, at z~0, are in a cluster)

  17. Initial spatial distribution within patch (at z~1000)... …stochastic (initial conditions Gaussian random field); study `forest’ of merger history ‘trees’ …encodes information about subsequent ‘merger history’ of object (Mo & White 1996; Sheth 1996)

  18. (Reed et al. 2003) The Halo Mass Function • Hierarchical; no massive halos at high-z • Halo abundance evolves strongly • Massive halos (exponentially) rare • Observable → mass difficult (current parameterizations by Sheth & Tormen 1999; Jenkins et al. 2001)

  19. Universal form? • Spherical evolution (Press & Schechter 1974; Bond et al. 1991) • Ellipsoidal evolution (Sheth & Tormen 1999; Sheth, Mo & Tormen 2001) • Simplifies analysis of cluster abundances (e.g. ACT) Jenkins et al. 2001

  20. Most massive halos populate densest regions over-dense under-dense Key to understand galaxy biasing (Mo & White 1996; Sheth & Tormen 2002) n(m|d) = [1 + b(m)d] n(m)

  21. Halo clustering • Massive halos more strongly clustered • Clustering of halos different from clustering of mass massive halos non- linear theory dark matter Percival et al. 2003

  22. Halo clustering  Halo abundances Clustering is ideal (only?) mass calibrator (Sheth & Tormen 1999)

  23. The halo-model of clustering • Two types of pairs: both particles in same halo, or particles in different halos • ξdm(r) =ξ1h(r) + ξ2h(r) • All physics can be decomposed similarly: influences from within halo, versus from outside

  24. The dark-matter correlation function ξdm(r) =ξ1h(r) + ξ2h(r) • ξ1h(r)~∫dm n(m) m2ξdm(m|r)/r2 • n(m): number density of halos • m2: total number of pairs • ξdm(m|r): fraction of pairs which have separation r; depends on density profile within m-halos • Need not know spatial distribution of halos! • This term only matters on scales smaller than the virial radius of a typical M* halo (~ Mpc) • ξ2h(r) ~ larger scales, depends on halo clustering

  25. Clustering in simulations • Expect (and see) feature on scale of transition from one- halo to two-halo • Feature in data? ξdm(r) =ξ1h(r) + ξ2h(r)

  26. Galaxy formation • Gas cools in virialized dark matter ‘halos’. Physics of halos is nonlinear, but primarily gravitational • Complicated gastrophysics (star formation, supernovae enrichment, etc.) mainly determined by local environment (i.e., by parent halo), not by surrounding halos

  27. (Cole et al. 2000)

  28. Kauffmann, Diaferio, Colberg & White 1999 Also Cole et al., Benson et al., Somerville & Primack, Colin et al. Colors indicate age

  29. Halo-model of galaxy clustering • Two types of pairs: only difference from dark matter is that now, number of pairs in m-halo is not m2 • ξdm(r) =ξ1h(r) + ξ2h(r) • Spatial distribution within halos is small-scale detail

  30. The galaxy correlation function ξdm(r) =ξ1h(r) + ξ2h(r) • ξ1h(r)~∫dm n(m) g2(m)ξdm(m|r)/r2 • n(m): number density of halos • g2(m): total number of galaxy pairs • ξdm(m|r): fraction of pairs which have separation r; depends on density profile within m-halos • Need not know spatial distribution of halos! • This term only matters on scales smaller than the virial radius of a typical M* halo (~ Mpc) • ξ2h(r) ~ larger scales, depends on halo clustering

  31. Type-dependent clustering: Why? populate massive halos populate lower mass halos Spatial distribution within halos second order effect (on >100 kpc)

  32. Comparison with simulations Sheth et al. 2001 steeper • Halo model calculation of x(r) • Red galaxies • Dark matter • Blue galaxies • Note inflection at scale of transition from 1-halo term to 2-halo term • Bias constant at large r shallower x1h›x2h x1h‹x2h →

  33. A Nonlinear and Biased View • Observations of galaxy clustering on large scales provide information about cosmology (because clustering on large scales is still in the ‘linear’ regime) • Observations of small scale galaxy clustering provide a nonlinear, biased view of the dark matter density field, but they do contain a wealth of information about galaxy formation • g(m) characterizes this information and so can inform galaxy formation models

  34. Summary • Hierarchical clustering = cosmic capitalism: Many models (percolation, coagulation, random walks) give equivalent descriptions • All models separate cosmology/dynamics from statistics P(k) • Gastrophysics determined by mass of parent halo • All effects of density (environment) arise through halo bias (massive halos populate densest regions) • Description quite detailed; language of halo model also useful for other ‘biased’ observables

  35. Halo Model • Describes spatial statistics well • Describes velocity statistics well • Since Momentum ~ mv, Temp ~ v2 ~ m2/3, and Pressure ~ Density ×Temp Halo Model useful language for interpreting Kinematic and Thermal SZ effects, various secondary contributions to CMB, and gravitational lensing (see Cooray & Sheth 2002 review) • Open problem: Describe Ly-a forest

  36. Marked correlation functions Weight galaxies by some observable (e.g. luminosity, color, SFR) when computing clustering statistics (standard analysis weights by zero or one)

  37. There’s more to the point(s) • Multi-band photometry becoming the norm • CCDs provide accurate photometry; possible to exploit more than just spatial information • How to estimate clustering of observables, over and above correlations which are due to spatial clustering? • Do galaxy properties depend on environment? Standard model says only dependence comes from parent halos…

  38. Luminosity as a mark • Mr from SDSS • BIK from semi-analytic • model • Little B-band light • associated with • close pairs; more B-band • light in ‘field’ than ‘clusters’ • Vice-versa in K • Feature at 3/h Mpc in all • bands: Same physical • process the cause? • e.g. galaxies form in groups • at the outskirts of clusters

  39. Colors and star formation • Close pairs tend to be redder • Scale on which feature • appears smaller at higher z: • clusters smaller at high-z? • Amplitude drops at lower z: • close red pairs merged? • Close pairs have small • star formation rates; scale • similar to that for color even • though curves show • opposite trends! • Same physics drives both • color and SFR?

  40. Stellar mass • Circles show M*, crosses show LK • Similar bumps, wiggles in both: offset related to rms M*, L • Evolution with time: M* grows more rapidly in dense regions

  41. Halo-model of marked correlations Again, write in terms of two components: W1gal(r) ~∫dm n(m) g2(m)‹W|m›2ξdm(m|r)/rgal2 W2gal(r) ≈ [∫dm n(m) g1(m) ‹W|m›b(m)/rgal]2ξdm(r) So, on large scales, expect 1+W(r) 1+ξ(r) 1 + BWξdm(r) 1 + bgalξdm(r) M(r) = =

  42. Conclusions (mark these words!) • Marked correlations represent efficient use of information in new high-quality multi-band datasets (there’s more to the points…) • No ad hoc division into cluster/field, bright/faint, etc. • Comparison of SDSS/SAMs ongoing • test Ngalaxies(m); • then test if rank ordering OK; • finally test actual values • Halo-model is natural language to interpret/model

  43. Halo-model calculations } • Type-dependent (n-pt) clustering • ISW and tracer population • SZ effect and halo shapes/motions • Weak gravitational lensing • Absorption line systems • Marked correlations Review in Cooray & Sheth 2002 } Work in progress

More Related