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Transcript
Problems in Chapter 13
Worked out for Geology/Physics 360
An
Illustration
of Parallax
using HNSKY
Sirius Now (today)
in March
Sirius in Sept.
2010 (6
months later)
Question: How would we find a closer star than Proxima Centauri?
Problem 3. The Parallax of the red giant Betelgeuse is just barely measurable and has a
value of about 0.005 arc seconds. What is its distance? Suppose the measurement is in
error by + or โ€“ 0.003 arc seconds. What limits can you set on its distance.
Answer: p(Betelgeuse) = 0.005 arc seconds. Therefore its distance is d = 1/p = 200 pc.
The error in this measurement is +/โ€“0.003", so we have to add and subtract this figure
from the parallax angle to give the lower and upper limits to the distance estimate.
d(pc) = 1/0.008 = 125 pc, the larger angle corresponds to the closer distance
d(pc) = 1/0.002 = 500 pc, the smaller angle corresponds to the farther distance
Problem 5. The star Rigel radiates most strongly at about 200 nm. What is its
temperature? How does this compare to the Sun.
๐€m for Rigel = 200 nm. Use Wienโ€™s Law to find its temperature?
T = 3 × 106 K nm / ๐€m = 3 × 106 K nm / 200 nm = 15,000 K.
This is much hotter than the surface of the Sun, which is about 6000 K. (2.5
times hotter). (Note that we have approximated the constant here as 3 x 106, it is
closer to 2.9 x 106
Problem 6. The bright southern star Alpha Centauri radiates most
strongly at about 500 nm. What is its temperature? How does this
compare to the Sun.
. Alpha Centauri has its peak radiation at 500 nm. Applying Wienโ€™s
Law,
T = 3 × 106 K nm / 500 nm = 6000 K.
The temperature of this star is approximately the same as our Sunโ€™s,
so Alpha Centauri has a similar spectral type to the Sun (G2).
Problem 7. Arcturus is about ½ as hot as the sun but is about 100 times more
luminous. What is its radius compared to the Sun.
. For Arcturus, T = To/2, where To is the temperature of the Sun. L = 100Lo. To
find the starโ€™s radius, use the Stefan-Boltzmann Law, which relates a starโ€™s
luminosity, L, to its temperature, T, and radius, R.
L = 4๐œซR2 ๐ˆ T4 or LArc = 4๐œซR2Arc ๐ˆ T4Arc and Lo = 4๐œซR2o ๐ˆ T4o
We want to find RArc in terms of Ro.
100 Lo = LArc = 4๐œซR2Arc ๐ˆ T4Arc
100 (4๐œซR2o ๐ˆT4o) = 4๐œซR2Arc ๐ˆ T4Arc
100 (R2oT4o) = R2Arc T4Arc = R2Arc (To/2) 4
100 (R2oT4o) = R2Arc (T4o) / 24
100 (R2o) = R2Arc / 16
1600 (R2o) = R2Arc
Therefore
R Arc = (1600) 1/2 Ro = 40 Ro
Arcturus is 40 times wider than the Sun.