Transcript galaxy.

Astronomy 2
Overview of the Universe
Spring 2007
11. Lectures on External Galaxies.
Joe Miller
Are the “spiral nebulae” extragalactic? Or, do we live in the
only galaxy in the universe? The age-old astronomy problem:
distance.
April 1920: the Curtis-Shapely debate
Shapely (Harvard): Argued that spiral nebulae were inside
our galaxy for several reasons
• Galaxy was huge (he didn’t know about dust).
• van Maanen’s observations showed that one spiral nebula,
M 101, could be observed to rotate. It it were outside our galaxy, it
would have to be turning faster than the speed of light.
• Spiral nebulae were never seen in the Milky Way: the “zone of
avoidance.” Therefore, their distribution acknowledged the geometry
of our galaxy, and they must be part of our galaxy.
• A nova, S Andromeda, was observed in the Andromeda Nebula. If this
nebula were outside our galaxy, the nova would have to be incredibly
bright, much brighter than known novae.
Curtis-Shapely debate (cont.)
Curtis (Lick): Argued that the spiral nebulae were other
galaxies, well outside our own galaxy:
• van Maanen must have made errors in his measurements of M101, and
it wasn’t rotating.
• The zone of avoidance must be an artifact of something in our galaxyperhaps dust extinction- blocking our view of galaxies in the Milky
Way.
• S Andromeda was not a normal nova. It was something else,
something much brighter.
• Slipher’s observations of several spiral nebulae showed that they had
large red Doppler shifts, indicating they were moving away from us at
very high speeds, speeds too high to be a part of our galaxy.
Shapely had the strongest arguments, but Curtis was right!
Edwin Hubble completely settled
the controversy.
He found a Cepheid variable star
in M 31, the Andromeda galaxy.
The period-luminosity
relationship for Cepheids defines
a close relationship between the
period of pulsation and the
absolute magnitude of the star.
Sine the apparent magnitude can
be measured directly, determining
the period of a Cepheid variable
gives a precise measurement of its
distance. Using present-day data,
it is about 700,000 pc from us. It
can be seen with the naked eye.
The universe is teeming with galaxies
M 31: nearest example of a large galaxy.
Has all the same components that are found in our galaxy:
globular star clusters, halo and disk stars, young star clusters,
dust, gas, etc.
Literally billions of galaxies can be recorded on images with
large modern telescopes. The vast majority are much further
away than M 31, and once again measuring distances is a
major problem.
The Realm of the Galaxies
The variety is enormous, and our
understanding of what is going on is a
work in progress!
Hubble’s “tuning fork” diagram.
Distances to galaxies
Measuring distance to galaxies:
1) Out to 10 million pc (~30 million with HST): Cepheids, O
and B stars, supergiants.
2) Tully-Fisher relationship: (100 million pc)
There is a relationship between the line width of a galaxy in
neutral hydrogen radiation, which measures rotation speed of
a galaxy, which is a measure of its mass, and the luminosity
of the galaxy. This works for spirals.
3) supernovae: billions of pc (appear to be quite good).
4) redshifts- a great discovery!
The expanding universe:
Hubble’s great discovery
The farther away a galaxy
is from us, the faster it is
moving away from us.
Since motion away from us
produces a Doppler shift
toward the red, it is
equivalent to say that the
redshifts of galaxies
increase with distance.
The Hubble diagram:
This does not mean we are at the center of the
universe. The entire universe is expanding, so the
distance between all galaxies is increasing (except ones
close enough to be bound together by gravity). If we
lived in another distant galaxy, we would see all
galaxies moving away from us.
The Hubble Constant
The Hubble constant H0 is the slope of the line in the Hubble diagram.
It is the rate of expansion, and the subscript “0” means the present
value of the constant. The universe could change its rate of
expansion.
One current value for the Hubble constant is around
H0 = 73 km/sec/Mpc
with an uncertainty of plus or minus about 5 km/sec/Mpc. This
means that outward velocities of galaxies increase 73 km/sec for
every Mpc (million pc) of increasing distance.
Using redshifts to derive distances:
Since the Hubble constant H0 is the slope of the line
in the Hubble diagram, we can write
c(


)  v  H0 d, where d is in Mpc. Therefore
d
Example:
v
H0
If v = 6500 km/sec, then 6500/65 = 100 Mpc. An
object with a redshift corresponding to a velocity of
6500 km/sec would be 100 million pc away.
Rotation of our galaxy allows mass determination
Masses of galaxies- a dark mystery. Dark matter.
It now appears that there is about 10 times as much
dark matter as ordinary matter! What it is remains a
mystery, but many think it is some kind of as yet
undiscovered elementary particle.
Galaxies often come in groups, ranging from a few
members to 1000’s of galaxies.
The Local Group- a small cluster
The building up of galaxies through merging
Additional evidence for dark matter:
Gravitational lensing
Once again, the amount of dark matter needed to
make these lenses work is about 10 times the visible
matter. The dark matter is not distributed exactly the
same as the visible light.
Radio astronomy: the discovery of radio galaxies,
active galaxies, and quasars.
Finally, a radio star is found!
Surprising result: this star is traveling away from us
at roughly 16% of the speed of light!!!
Major discovery: 3C 273 is found to vary
significantly in light output in days! It can’t be more
than a few light days in size.
Extreme energy generation from a very
compact region or new physics to explain
the redshifts.