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Cosmological Structure Formation A Short Course

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Predictions of inflation consistent with temperature anisotropies ... do FOF Groups ... agreement between virial mass and FOF mass. Dark Matter Halo Mass ... – PowerPoint PPT presentation

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Title: Cosmological Structure Formation A Short Course


1
Cosmological Structure FormationA Short Course
  • III. Structure Formation in the Non-Linear Regime
  • Chris Power

2
Recap
  • Cosmological inflation provides mechanism for
    generating density perturbations
  • which grow via gravitational instability
  • Predictions of inflation consistent with
    temperature anisotropies in the Cosmic Microwave
    Background.
  • Linear theory allows us to predict how small
    density perturbations grow, but breaks down when
    magnitude of perturbation approaches unity

3
Key Questions
  • What should we do when structure formation
    becomes non-linear?
  • Simple physical model -- spherical or top-hat
    collapse
  • Numerical (i.e. N-body) simulation
  • What does the Cold Dark Matter model predict for
    the structure of dark matter haloes?
  • When do the first stars from in the CDM model?

4
Spherical Collapse
  • Consider a spherically symmetric overdensity in
    an expanding background.
  • By Birkhoffs Theorem, can treat as an
    independent and scaled version of the Universe
  • Can investigate initial expansion with Hubble
    flow, turnaround, collapse and virialisation

5
Spherical Collapse
  • Friedmanns equation can be written as
  • Introduce the conformal time to simplify the
    solution of Friedmanns equation
  • Friedmanns equation can be rewritten as

6
Spherical Collapse
  • We can introduce the constant
  • which helps to further simplify our
    differential equation
  • For an overdensity, k-1 and so we obtain the
    following parametric equations for R and t

7
Spherical Collapse
  • Can expand the solutions for R and t as power
    series in ?
  • Consider the limit where ? is small we can
    ignore higher order terms and approximate R and t
    by
  • We can relate t and ? to obtain

8
Spherical Collapse
  • Expression for R(t) allows us to deduce the
    growth of the perturbation at early times.
  • This is the well known result for an Einstein de
    Sitter Universe
  • Can also look at the higher order term to obtain
    linear theory result

9
Spherical Collapse
  • Turnaround occurs at t?R/c, when Rmax2R. At
    this time, the density enhancment relative to the
    background is
  • Can define the collapse time -- or the point at
    which the halo virialises -- as t2?R/c, when
    RvirR. In this case
  • This is how simulators define the virial radius
    of a dark matter halo.

10
Defining Dark Matter Haloes
11
What do FOF Groups Correspond to?
  • Compute virial mass - for LCDM cosmology, use an
    overdensity criterion of , i.e.
  • Good agreement between virial mass and FOF mass

12
Dark Matter Halo Mass Profiles
  • Spherical averaged.
  • Navarro, Frenk White (1996) studied a large
    sample of dark matter haloes
  • Found that average equilibrium structure could be
    approximated by the NFW profile
  • Most hotly debated paper of the last decade?

13
Dark Matter Halo Mass Profiles
Dark Matter Halo Mass Profiles
  • Most actively researched area in last decade!
  • Now understand effect of numerics.
  • Find that form of profile at small radii steeper
    than predicted by NFW.
  • Is this consistent with observational data?

14
What about Substructure?
  • High resolution simulations reveal that dark
    matter haloes (and CDM haloes in particular)
    contain a wealth of substructure.
  • How can we identify this substructure in an
    automated way?
  • Seek gravitationally bound groups of particles
    that are overdense relative to the background
    density of the host halo.

15
Numerical Considerations
  • We expect the amount of substructure resolved in
    a simulation to be sensitive to the mass
    resolution of the simulation
  • Efficient (parallel) algorithms becoming
    increasingly important.
  • Still very much work in progress!

16
The Semi-Analytic Recipe
  • Seminal papers by White Frenk (1991) and Cole
    et al (2000)
  • Track halo (and galaxy) growth via merger history
  • Underpins most theoretical predictions
  • Foundations of Mock Catalogues (e.g. 2dFGRS)

17
The First Stars
  • Dark matter haloes must have been massive enough
    to support molecular cooling
  • This depends on the cosmology and in particular
    on the power spectrum normalisation
  • First stars form earlier if structure forms
    earlier
  • Consequences for Reionisation

18
Some Useful Reading
  • General
  • Cosmology The Origin and Structure of the
    Universe by Coles and Lucchin
  • Physical Cosmology by John Peacock
  • Cosmological Inflation
  • Cosmological Inflation and Large Scale
    Structure by Liddle and Lyth
  • Linear Perturbation Theory
  • Large Scale Structure of the Universe by
    Peebles
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