Prelab:
In your lab book, draw a blackbody curve for
the star Deneb; see Appendix 5 (the table of the visually brightest
stars).
a)
Make sure that your axes are labeled
properly.
b)
Calculate the wavelength of maximum intensity (or flux), so that you
know where
the visible spectrum is relative to that wavelength of max intensity.
c)
Label where the red and blue parts of the spectrum are on your
blackbody
diagram.
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PALOMAR SKY SURVEY PRINTS: INTERSTELLAR MATTER
May 28, 2007
PLEASE BE CAREFUL when
using these
photographic prints.
Do NOT touch with pen or
pencil.
Do NOT write on paper
that lies over
the prints.
The 48-inch telescope on
The prints are negatives. Stars therefore show up black; the brighter
the star, the larger the star image on the print. For
nebulae and galaxies, this means that the
brighter they appear in the sky, the darker
they appear on the prints. (This is, of course, opposite to most of the
photographs in the text, in which stars, nebulae, and galaxies appear
white.)
These prints are
important research tools actually
used by astronomers to discover new objects and to study the various
kinds of
stars, interstellar matter, and galaxies that make up our universe.
The four prints to be
studied are O,E 1099 and O,E
754. The former prints cover a region
immediately to the north (to the top) of the latter prints. Both regions are part of the constellation
Cygnus, a part of the sky through which the Milky Way runs. There is an overlap of about 1inch between
the two sets of prints.
I realize that the
reading will be out of context
somewhat (the reading for each section is on top of the various pages
that
follow), but try to extract the important stuff out (how the nebula
looks, why
it looks that way, what excites the fluorescence mechanism, and
how/where the
nebula fits in the context of stellar life and evolution).
It's also important to read the captions to
all associated pictures.
A)
RED and BLUE on the Palomar Prints
First decide which of the
prints (O or E) is
blue-sensitive (400 nm) and which is the red-sensitive
(640 nm).
One
simple way to do this is by using the fact that the very bright star on
the
prints is Deneb
( = a Cygni), one of the 20
brightest-appearing stars in the sky.
Determine the wavelength at which Deneb is brightest.
Now draw a blackbody
curve for Deneb, labeling the
wavelength of Deneb's maximum intensity and the two wavelengths of the
prints'
maximum sensitivity.
With this result in mind,
compare the two prints (O
and E 754) and decide which print is the blue-sensitive one and which
is the
red. Be convincing.
Using prints E and O
1099, find a reasonably
bright
a) blue
star
b) red
star
c) yellow
star
List positions (in the
form of LxT, where L =
distance from the left edge of the print in centimeters and T =
distance from
the top edge of the print in centimeters) of these two stars picked
below.
(Make sure you know which
edges of the print are top
and left before making measurements!)
In each case, explain the
reason for how you knew it
was the color star that you claimed.
B) H II REGIONS (or
EMISSION
NEBULAE): Kaufmann, section 20-2 and
H II regions (pronounced
"H two" regions;
the "two," II, means that the hydrogen is ionized) are concentrations
of matter where the hydrogen is completely ionized by the ultraviolet
energy
radiated from nearby hot blue
stars. As the text emphasizes, the
strongest visible bright line emitted is the Balmer H-alpha line of
hydrogen
(the 3 --> 2 transition), at a
wavelength of
656 nm, in the red part of the visible spectrum. Do
the H II regions in fact show up darker on
the print that you chose as the red-sensitive one?
AGE DETERMINATION OF H II
REGIONS:
method 1
Since H II regions only
surround young O and B stars,
these nebulae must be young also. Radial
velocity data (from the Doppler shift in the spectrum) show that these
regions
are slowly expanding about their central stars.
Since this expansion will cause a decrease in the gas density,
the
intensity (i.e., how black they are on the print) of H II regions
should also
decrease as they get older. Which of the H II regions (on print 754)
would you
judge to be the youngest by this criterion?
Identify by position.
List at least four
assumptions you implicitly made in
using this criterion to judge the relative ages of the H II regions;
one
example is given:
1) the
HII
regions initially (at birth) had the same hydrogen gas density
AGE DETERMINATION OF H II
REGIONS: method 2
Another indication of age
is the structure of the
dust clouds that are often associated with H II regions.
If the dust (which shows up "white"
on the negative) shows distinct striations, the dust patterns must be
rather
young, since the clouds' expansion causes the striations to diffuse
gradually
with age. According to this age
criterion, which H II region on print 754 would you judge to be
youngest? Again identify by position.
List some assumptions you
implicitly made in using
this criterion to judge the relative ages of the H II regions.
Did you pick the same
nebulae with both criteria
above? If not, why do you think
not?
Look for an HII region
called the Pelican Nebula on
print 754. The pelican is standing
upright and is about 1 inch tall.
Do not
spend more than 1 minute looking for it.
C) PLANETARY
NEBULAE: Kaufmann
section 22-3;
Planetary nebulae are
slowly expanding gas shells
surrounding very hot white dwarfs.
The
radiation from the shell is very similar to that we receive from an H
II
region: the Balmer H-alpha line is again
very strong in the red part of the spectrum; the
planetary
nebula should therefore show up better on a red-sensitive photograph. Try to find one on print E1099.
[It's less than 1/8 inch in size, but it does
look sort of like the pictures in the book on page 510 or like the
picture of M97 on the Messier
object chart by my office.]
1)
Determine
the diameter of this nebula in light years; the distance to the nebula
is about
3000 c-yr.
You are responsible for
including
all the important steps of the method (diagram, trig, etc.)
2) Once you've found the
nebula on the red print, can
you find it on the blue print? (spend no more than 1 minute)
3) The expansion speed of
the nebula is about 25
km/sec; where does the information come from?
Determine
how long ago in years the white dwarf ejected the gas shell.
4)
Is the age
you've just calculated most likely an underestimate or an overestimate? Why?
State/justify the assumption(s) you made
in your calculations.
D) INTERSTELLAR DUST:
Kaufmann
section 20-2
Absorption due to
interstellar dust shows up on these
negative prints as a white spot, cloud, or streak.
The "white" indicates the
"absence" of stars in that particular region of the sky.
Of course, the stars are not really absent
there, it's just that much of their light has been absorbed by the dust. Print 754 shows this effect particularly
well.
Which wavelengths, red or
blue, are more greatly
absorbed (and re-emitted, of course; i.e., scattered) by the dust? Why is this?
Is this the print on which the dust shows up better? Explain.
Stars between the dust
clouds and earth are
unaffected by the dust while stars behind the clouds may be dimmed to
such an
extent that none (or very little) of their light can shine through. Therefore, all of the stars seen
"on" such a dust cloud are between us and the cloud.
With this in mind, can you think of a way to
estimate the relative distances to the dust clouds on the print? Describe your method clearly.
Of the two dust clouds
located at 3x25 cm and 27x30
cm on E754, which do you judge to be nearer?
Why? Can you be
quantitative?
Give three assumptions
that are implicit in the
method you used above.
On what sections of the
print (754) is the dust least
dense? positions?
In these dust free
regions, we are looking farthest
into space.
Estimate the number of stars
in a small square portion of print 754 in a region where the dust
is very dense and in a region where the dust is least dense.
position of a "dusty"
region &
star count?
position of a non-dusty
region &
star count?
No galaxies are visible
on either print. (Compare, for example,
two other prints
available.)
Is this expected or
unexpected? Why?
E) MYSTERY NEBULAE:
Kaufmann section 20-2
You have learned about
several different types of
nebulae in this course. Look at the
3
bright nebulae on prints O/E-754 at positions: 27-28 x 17-18 cm.
By determining the color of the nebulae and
the stars inside, determine the type of nebula they are and the types
of
nebulae that they are not. Explain.
F) SUPERNOVA FILAMENTS:
Kaufmann
section 20-8
Filaments of gas are very
prominent on print
E1099. They are red due to the hydrogen
emission at 656 nm, just like the H II regions previously studied (in
A) are,
except that there are no hot blue stars near enough to ionize the gas. So what could be exciting or ionizing the gas
in the filaments? One suggestion is that
the gas is ionized by the shock wave released during a long-ago
supernova
explosion. As the shock wave passes
through the interstellar medium, it collisionally excites the hydrogen
gas to
fluorescence.
Notice that the filaments
on E 1099 are slightly
curved. Where do you judge the apparent center from which these
filaments have
apparently been blasted to be?
Behind the dust clouds in
the center of print 754
there is a radio and x-ray emitting source (Cygnus X-3), perhaps the
remnant of
a supernova.
Choose one of the
filaments on print E1099.
If the filaments lie at a distance of 3000
light years from earth, determine the radius of curvature of the
filament arc
in light years.
(Use the same method
that you used in determining the size of the
planetary
nebula.)
Draw a large,
well-labeled diagram of the prints,
showing the curvature that you see, the apparent center, etc.; show all
work.
How long ago (roughly)
did this supernova
explode?