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- The Formation of Galaxies and Large Scale Structures in the Universe
- Combes et al. chapter 12, also Longair (chapter 11-15)
- Other: exams due – any discussion?
- Observing Project reports not graded yet
- Discuss Proposal Project (another handout)
- Mini-TAC exercise for next week (handed out Wed.)
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3
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4
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- Jean’s criteria governs “small scale” collapse due to self-gravitation
- Treated as stability vs. perturbation in an infinite homogeneous medium
in equilibrium
- For fluid with a pressure P = ρ0vs2,
then perturbations with λ > vs(G ρ0)-1/2
= λJ are unstable.
- Basically, does the disturbance have time to cross in a freefall time,
tff = (Gρ)-1/2? If so, then pressure forces are
negligible.
- The sound crossing time is r/vs, which gives the λJ
criteria
- For galaxies, we can write an effective pressure in terms of the
velocity dispersion: λ > σ(G ρ0)-1/2
= λJ
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6
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7
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11
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12
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14
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15
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18
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19
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- “Sea” of photons. Photon Energy
Density is proportional to 1/R4. Note that the text has this
WRONG. Photon number density
changes as 1/R3, but wavelengths stretch out. Anyway, proceeding…
- Recall the linearized perturbation equation
- Set y = ρx/ργ = R/R(teq)
where there is an equilibrium time where the two densities are equal.
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- From Combes et al., of CDM structure simulations.
- They kind of work.
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- Homogeneity scale is D>100 Mpc.
What of smaller perturbations?
- Initial origin unknown. A power
spectrum is postulated (as gravity does not have a characteristic
scale):
- δρ/ρ = δM/M = AM –α
- Significant perturbations on small scales would mean an excess of
primordial black holes, and we don’t see much on the largest scales,
which means alpha isn’t too large.
- Adjust the amplitude A to match observation.
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- Do perturbations affect entropy per baryon? If not, then they are adiabatic:
- δs/s = 3δT/T – δns/ns = 0
- δT/T=1/3 δρ/ρ
- Whereas for isothermal:
- T = constant
- δs/s = δns/ns and no T fluctuations, and
the photon to baryon ratio must vary
- Jeans mass is limit of growth vs. acoustic action
- When universe was radiation dominated sound speed was order of light
speed (divided by root 3).
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- LJ ~ ctexp ~ Lhorizon
- This increases with the expansion, until recombination. At this time…
- Universe becomes matter dominated with density going as 1/R3
and 1/Tγ3.
Sound speed goes as 1/R, and so Jeans’ mass goes as R-3/2.
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- Contrasting possible isothermal and adiabatic scenarios. See Rees (1984) for more details.
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34
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- Pancake model: HDM or adiabatic baryons you get a characteristic
collapse scale. “Azita’s House of
Pancakes.” Galaxies form from
pancake fragmentation.
- Heirarchical scenarios.
Isothermal fluctuations or CDM gives no cutoff at small
scales. Some details in the text
for particular cosmologies (which we will wait on).
- Numerical simulations pay a serious role here.
- More details in text, but we’re rush, rush, rush at this point. Feel the knowledge flooding your
brain, but don’t drown!
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35
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- Movie simulation of galaxy formation via assembly of small pieces
(courtesy of Space Telescope Science Institute):
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39
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- DIRECTLY related to models by the fact of galaxy formation and
evolution. Everything must be
self-consistent or the model must be discarded.
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42
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43
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44
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- Cf. Boyle and Terlevich 1998 that compared quasars and stars.
- After Madau et al. 1996 (called the “Madau plot” even)
- Must reconcile with galaxy formation + evolution scenarios. Right?
- Highest redshifts unclear, but some rise and then steep fall off. Epoch of galaxy formation still
unclear.
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- We’ve talked around the crux of things: cosmology. How does spacetime itself evolve? How is redshifted related to distance,
look-back time, etc.?
- Will look at some specific formulations of distances and more (Hogg et
al. pedagogical stuff) and classical formations, plus latest WMAP
results.
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Notes
