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STRUCTURE FORMATION MATTEO VIEL INAF and INFN Trieste SISSA - 28,th February/ 3rd March 2011 OUTLINE: LECTURES 1. Structure formation: tools and the high redshift universe 2. The dark ages and the universe at 21cm 3. IGM cosmology at z=2=6 4. IGM astrophysics at z=2-6 5. Low redshift: gas and galaxies 6. Cosmological probes LCDM scenario OUTLINE: LECTURE 1 Tools for structure formation: Press & Schecther theory Power spectrum, Bispectrum Books: Coles & Lucchin, Peacock (chapter 15) Results from numerical simulations Importance of first structure for particle physics and cosmology LINEAR THEORY OF DENSITY FLUCTUATIONS-I Newtonian equations for the evolution of density and velocity under the influence of an external gravitational potential (see also Jeans theory) Convective derivative = comoving derivative We still miss Poisson equation and an equation of state relating p and r Change of variable in an expanding universe: Comoving position Peculiar vel. Density contrast Conformal time New fluids equations: New term Euler equation In absence of pressure and forces v ~ 1/a Check also Peacock’s book Sect. 15.2 LINEAR THEORY OF DENSITY FLUCTUATIONS-II Poisson’s equation 1- take divergence of Euler equation 2- eliminate gradient of v using continuity 3- use Poisson pressure-free dust universe Pressure-free dust universe + Eds Growing mode Decaying mode LINEAR THEORY OF DENSITY FLUCTUATIONS-III Check also Peebles 1980, sects.10-13 Open universe L=0 Flat universe k=0 EdS at high-redshift to Low W at low redshift is faster in LCDM Zel’dovich approximation for structure formation Self-similar growth of density structures with time (Note that in Eds potent is const) Euler equation in linearized form D o LINEAR THEORY OF DENSITY FLUCTUATIONS-IV Zel’dovich (1970) Formulation of linear theory Lagrangian in nature: extrapolate particles positions in the early universe, kinematic approximation Pancakes, optimized Zel’dovich approximations schemes, application to galatic spin This approximation neglects non-linear evolution of the acceleration and uses Linear theory even in the non-linear regime LINEAR THEORY OF DENSITY FLUCTUATIONS-V Viel et al. 2002 LINEAR THEORY OF DENSITY FLUCTUATIONS: SPHERICAL COLLAPSE Simplest model for the formation of an object Birkhoff’s theorem in GR Evolution of the scale factor a First integral of evolution equation Solutions E<0 For small h values Extrapolation of linear theory describes the non-linear collapse of an object See also ellipsoidal collapse PS THEORY - I PS THEORY - II A method is needed for partitioning the density field at some initial time ti into a set of disjoint regions each of which will form a nonlinear object at a time tf Filtering scale R Key-assumption: ds is a random Gaussian field d c = 1.686 Time enters D Mass enters D0 and its derivative PS THEORY - III Diachronic U~l 1/5 Synchronic U ~ l2 a determines dependence of mass variance on volume Bond et al. 1991 Initial overdensity Excursion set approach to mass functions -I Variance of smoothed field Low res High res Markov Chains Initial overdensity Excursion set approach to mass functions-II iii) Is the first upcrossing point! Variance of smoothed field Low res High res Same press & schechter derivation but with right factor 2 interpreted in a probabilistic way using Markov Chains in Fourier space Excursion set approach to mass functions: random walks Excursion set approach to mass functions: random walks - II Excursion set approach to mass functions: random walks - III Excursion set approach to mass functions: random walks - IV PS within merger tree theory - I Conditional probability Of course important for any galaxy formation (or structure formation) model Press & Schecter theory or N-body simulations are now the inputs of any cosmological model of structure formation PS within merger tree theory - II Probability of having a M1 prog Hierarchical formation but self-similarity is broken Distribution of formation Redshifts M/2 M n=0 n=-2,-1,1 . Sheth & Tormen mass function Sheth & Tormen 1998 PS74 ST98 Universal N-body calibrated mass function for many cosmological models (p=0.3, A=0.332,a=0.707) Mass function and its evolution Reed et al. 2003, MNRAS, 346, 565 In practice it is better to compute mass variance in Fourier space: KEY INGREDIENT IS MASS VARIANCE AND DEPENDS ON P(k) Mass function and its evolution -II High redshift SDSS QSOs Reionization sources First stars KEY INGREDIENT FOR HIGH REDSHIFT COSMOLOGICAL MODELS Summary of theory Linear theory simple and powerful: modes scale as scale factor Press & Schecter is a relatively good fit to the data Support for a hierarchical scenario of structure formation for the dominant dark matter component (baryons are a separate issue at this stage) Springel, Frenk, White, Nature 2006 Formation of structures in the high redshift universe - I Main results found recently: Typical first generation haloes are similar in mass to the free-streaming mass limit (Earth mass or below) They form at high redshift (universe is denser) and are thus dense and resistant to later tidal disruption The mass is primarily in small haloes at z>20 Structure builds up from small mass (Earth like) to large (e.g. MW) by a subsequence of mergers Formation of structures in the high redshift universe - II Primordial CDM inhomogeneities are smeared out by collisional damping and free-streaming Damping scale depends on the actual dark matter model but tipically is sub-parsec Green, Hofmann, Schwarz 2004, MNRAS, 353, L23 Sharp cutoff generation of haloes form abruptly. Mass variance independent of mass and many masses collapse RAPID SLOW Comparing a cluster at z=0 with high redshift assembly of matter Diemand, Kuhlen, Madau (2006) Subhaloes population at z=0 Kuhlen, Diemand, Madau, Zemp, 2008, Subhaloes are self-similar and cuspy Tidally truncated in the outer regions Main halo Subhaloes Proxy for halo mass Using extended Press & Schecter (EPS) for the high-z universe Taken from Simon’s White talk at GGI (Florence) on February 10th 2009 Using extended Press & Schecter (EPS) for the high-z universe-II Using extended Press & Schecter (EPS) for the high-z universe-III Numerical N-body effects largerly affected by missing large scale power Using extended Press & Schecter (EPS) for the high-z universe-IV Numerical N-body effects largerly affected by missing large scale power Using extended Press & Schecter (EPS) for the high-z universe-V Numerical N-body effects largerly affected by missing large scale power Using extended Press & Schecter (EPS) for the high-z universe-VI Numerical N-body effects largerly affected by missing large scale power Using extended Press & Schecter (EPS) for the high-z universe-VII Using extended Press & Schecter (EPS) for the high-z universe CONCLUSIONS: Important for detection Important for first stars Important for diffuse HI FURTHER STATISTICAL TOOLS STATISTICS OF DENSITY FIELDS 0-pt, 1-pt, 2-pt, 3-pt,……. n-pt statistics of the density field Ideally one would like to deal with d DARK MATTER in practice d ASTROPHYSICAL OBJECTS (galaxies,HI, etc…) 0-pt: calculate the mean density 1-pt: calculate probability distribution function (pdf) 2-pt: calculate correlations between pixels at different distances (powerspectrum) 3-pt: calculate correlations in triangles (bispectrum) Viel, Colberg, Kim 2008 The power spectrum P(k) Correlation function Density contrast Power spectral density of A The power spectrum P(k): an example of its importance Cutoff in the P(k) sets transition matter-radiation: fluctuations below this scale cannot collapse in the radiation era k eq ~ 0.075 Wm h2 Nichol arXiv: 0708.2824 z eq ~ 25000 Wm h2 The bispectrum Use Gaussian part -- NonGaussian part Note that in the pure gaussian case The statistics is fully determined by the Power spectrum Applied by Verde et al. (2002) on 2dF galaxies To measure b1=1 Matarrese, Verde, Heavens 1997 – Fry 1994 A connection to particle physics and gamma rays The density profile convergence The number of sub-haloes Extrapolating a bit…. !!! DM around the sun g-rays SUMMARY 1 – Linear theory + Press & Schechter: simple tool to get abundance of collapsed haloes at any redshift 2- Sheth & Tormen and other fitting N-body based formulae Importance of describing the number of haloes at high redshift as a potentially fundamental cosmological tool 3- Numerical simulations and EPS in the high redshift universe (neutralino dark matter) 4- Further statistical tools (power spectrum, bispectrum mainly) 5- The link to the z~0 universe. Perspectives for indirect DM detection