Astr 1050     Mon., Nov. 18, 2002
   Today:  Finish Chapter 14, Active Galaxies
             “Town Meeting” (Noon class)

Homework #9
Q1. You observe two Cepheid variable stars, A and B, which have the same average apparent magnitude. Star A brightens and dims with a period of 5 days, star B has a period of 18 days. Which is closer to Earth?
Faster varying variables are less luminous, therefore Star A is less luminous than B. Therefore if Star A appears as bright from Earth as B, it must be closer.
Q2. Which of the following is not a characteristic of the stars of the disk component of our galaxy?
Randomly inclined orbits
Q3. If all the mass in our galaxy were centrally concentrated, we'd expect velocities to fall with increasing distance according to Kepler's laws. This is not seen in the disks of spiral galaxies. Galactic rotation curves appear "flat" with increasing distance. This must be due to:
The gravitaional influence of "dark matter" in the halo.
Q4.  If the sun is 5 billion years old, how many times has it orbited the galaxy? Assume a circular orbit for the sun.
Need velocity of the sun (about 220 km/s) and the orbital circumference (2πr), where r=8. 5kpc.  Number of orbits in 5 billion years is then 5 billion years/time for one orbit, which is circumference/220 km/s.  Converting units gives an orbital period of 240 million years.  Therefore in 5 billion years the sun has orbited about 21 times.
Q5. If interstellar dust makes and RR Lyrae star look 1 magnitude fainter than it should, by how much will we overestimate its distance?
Star looks 1 mag fainter.  Distance = 10 (m-M+5)/5 so our estimate will differ by a factor of 101/5 which is about 1.6.

Accretion Disks
Black hole is “active” only if gas is present to spiral into it
Isolated stars just orbit black hole same as they would any other mass
Gas collides, tries to slow due to friction, and so spirals in (and heats up)
Conservation of angular momentum causes gas to form a disk as it spirals in

Different Views of the Accretion Disk
The torus of gas and dust can block part of our view
Seyfert 2 galaxies: Edge on view
Only gas well above and below disk is visible
See only “slow” gas
Ž narrow emission lines
Seyfert 1 galaxies: Slightly tilted view
Hot high velocity gas close to black hole is visible
High velocities  
Ž broad emission lines
BL Lac objects: Pole on view
Looking right down the jet at central region
Extremely bright – vary on time scales of hours
Quasars: Very active AGN at large distances
Can barely make out the galaxy surrounding them
Were apparently more common in distant past

Different Views of the Accretion Disk
The torus of gas and dust can block part of our view
Seyfert 2 galaxies: Edge on view
Only gas well above and below disk is visible
See only “slow” gas
Ž narrow emission lines
Seyfert 1 galaxies: Slightly tilted view
Hot high velocity gas close to black hole is visible
High velocities  
Ž broad emission lines
BL Lac objects: Pole on view
Looking right down the jet at central region
Extremely bright – vary on time scales of hours
Quasars: Very active AGN at large distances
Can barely make out the galaxy surrounding them
Were apparently more common in distant past

Different Views of the Accretion Disk
The torus of gas and dust can block part of our view
Seyfert 2 galaxies: Edge on view
Only gas well above and below disk is visible
See only “slow” gas
Ž narrow emission lines
Seyfert 1 galaxies: Slightly tilted view
Hot high velocity gas close to black hole is visible
High velocities  
Ž broad emission lines
BL Lac objects: Pole on view
Looking right down the jet at central region
Extremely bright – vary on time scales of hours
Quasars: Very active AGN at large distances
Can barely make out the galaxy surrounding them
Were more common in distant past

Quasar Images 1

Nice, early Quasar Quote:

Quasar Images II

Quasar Images III: “Starburst-Quasar”

What makes an AGN active?
Need a supply of gas to feed to the black hole
(Black holes from 1 million to >1 billion solar masses!
Scales as a few percent of galaxy bulge mass.)
Collisions disturb regular orbits of stars and gas clouds
Could feed more gas to the central region
Galactic orbits were less organized as galaxies were forming, also recall the “hierarchical” galaxy formation
Expect more gas to flow to central region when galaxies are young => Quasars (“quasar epoch” around z=2 to z=3)
Most galaxies may have massive black holes in them
They are just less active now because gas supply is less

Movie of an AGN ignition
Won’t show this one in class – but you can look at it on your own if you wish.  Shows a bulge of a spiral galaxy rapidly “ignite” as a central black hole is fuelled:
http://imgsrc.stsci.edu/op/pubinfo/mpeg/quasar.mpg

The Central Engine of Centaurus A
http://imgsrc.stsci.edu/op/pubinfo/pr/1998/14/content/centauf.mov

Gravitational Lensing

Chapter 14: Galaxies with Active Nuclei
Discovery of Active Galactic Nuclei (AGN)
Seyfert Galaxies and Radio Sources
The Unified Model
Black Holes in Galaxies, disks, orientation, +
Quasars
Distances and Relativistic Redshifts
Quasars as extreme AGN
Evolution of Quasars/Galaxies
Gravitational Lensing

Chapter 15: Cosmology
The Hubble Expansion -- review
Olber’s paradox
The Big Bang
Refining the Big Bang
Details of the Big Bang
General Relativity
Cosmological Constant
Origin of Structure