|
1
|
- Today: Textbook
Ordering
- Astro-ph (xxx.lanl.gov)
- WIRO: not this weekend
- Assignment for Friday check
- Email feedback please
- Longair, Ch. 2 (Large Scale Struct.)
- Unless noted, all figs and eqs from Longair.
- Note: This class will meet
W&F, 5440 will be M&W
|
|
2
|
- Astro-ph preprints for the week:
- http://xxx.lanl.gov/astro-ph
- Keep looking – we’ll do this every week.
- Discuss homework assignment
- My solution and ancillary source files will be posted on the webpage
(e.g., LaTex, sm, etc.)
|
|
3
|
- Hubble Expansion
- Black Body Background Radiation
- Light Element Abundances
- Age of oldest stars consistent with Ho age
|
|
4
|
- Isotropy – the universe looks the same in all directions, again
strictly true on large scales
- Small Baryon/Anti-baryon asymmetry
- Close to critical (Omega = 1) (will be HW)
- Initial fluctuations to seed structure growth
|
|
5
|
- Large scale distribution of radiation and matter in the Universe as
determined through observational work.
- Cosmic Microwave Background Radiation
- Large-scale Distribution of Galaxies
- Hubble’s Law
|
|
6
|
- First detected by Wilson and Penzias in 1960’s
- Serendipitous detection – thought is was noise in their radio
telescope but couldn’t find cause. Only later heard of theoretical
predictions
- Best spectrum observed by COBE satellite
- Red curve is theoretical prediction
- 43 Observed data points plotted there
error bars so small they are covered by curve.
- it is covered by curve.
- Isotropy also measured by COBE
- T varies by less than 0.01 K across sky
- Small “dipole” anisotropy seen
- Blue = 2.721
Red = 2.729
- Caused by motion of Milky Way falling towards the Virgo supercluster.
|
|
7
|
- Some Hubble studies performed using the CMBR as the reference-frame for
galaxy velocities.
Heliocentric velocities are relative to the sun, and there is
still the motion of the sun around the Milky Way (about 225 km/s) and
the motion of the Milky Way.
- Who will volunteer to do a short presentation on the MAP and PLANCK
missions next week?
|
|
8
|
|
|
9
|
- Zeldovich and Sunyaev in late 1960s:
- Injection of energy at z > 1000, then leads to an equilibrium
Bose-Einstein spectrum which depends on a dimensionless chemical
potential μ:
|
|
10
|
- Zeldovich and Sunyaev in late 1960s:
- Compton scattering by hot electrons in the IGM leads to a distortion of
the background spectrum:
|
|
11
|
|
|
12
|
- Verify by next Friday that if you redshift a blackbody spectrum that the
spectrum remains a blackbody and that the blackbody temperature changes
by a factor of 1+z. You need
not turn this assignment in, but I may ask someone to demonstrate this
on the blackboard.
|
|
13
|
|
|
14
|
- On small scales, the universe is very inhomogeneous (stars,
galaxies). What about larger
scales?
- Angular two-point correlation function w(θ):
|
|
15
|
- This function w(θ) describes apparent clustering on the sky down to
some magnitude limit.
- More physically meaningful is the spatial two-point correlation function
ξ(r) which describes clustering in 3-D about a galaxy:
|
|
16
|
- w(θ) isn’t so hard to measure from various surveys –
just need positions.
- ξ(r) is harder –
must have redshifts to do properly.
Can make some assumptions however.
|
|
17
|
|
|
18
|
|
|
19
|
|
|
20
|
|
|
21
|
|
|
22
|
|
|
23
|
|
|
24
|
|
|
25
|
|
|
26
|
|
|
27
|
|
|
28
|
|
|
29
|
|
|
30
|
- On the largest scales it is appropriate to impose the conditions of
isotropy and homogeneity, plus uniform expansion.
- These simplifications plus GR provide relatively simple “world
models” that provide a framework for cosmology and the origin of
galaxies and other large scale structures.
|
|
31
|
|
Notes