Stars are incredibly big and incredibly far away. There is no way that we could measure their temperatures with a thermometer -
but still, we can know their temperatures to great accuracy.
From experiments on Earth, we know that all hot objects give off
light. The objects give off light at many different wavelengths, but each object has a continuum peak wavelength
at which they emit more light than at any other wavelength.
The continuum peak wavelength is symbolized by λpeak (with the Greek letter "lambda"). We know
from experiments on Earth that the continuum peak wavelength of light emitted by an object is inversely proportional to its temperature. That
proportion can be symbolized by the equation:
Notice that because this is an inverse relationship, the longer the peak wavelength, the lower the temperature. Also, remember that the
continuum refers to the overall shape of a spectrum. A spectrum that was only due to temperature is shown on the left of the image below; the
spectrum of a real star is shown on the right.
Look at the spectrum of a real star, shown above and to the right. The overall shape of the spectrum peaks at about
4500 Ångstroms, so its continuum peak wavelength is 4500 Ångstroms.
Question 8. Which is hotter: a star that peaks at 5000 Ångstroms or a star that peaks at 6000
Ångstroms? How do you know?
|
Explore 4.
Look at the spectra of these seven stars (page will open in a new window).
These are the same seven stars from when you classified by line strength; they are available as a FlashPaper File
(requires free
Flash Player) or as a PDF (requires free Adobe
Reader).
For this exercise, you can ignore the zoom-in beneath each panel. For each spectrum, trace the underlying continuum shape - this is what
the spectrum would look like if it had no emission or absorption lines. Find the continuum peak wavelength for each star. If the peak is not shown on
the graph then estimate where you think it might peak.
Rank the stars according to peak wavelength of each star's thermal continuum, using the table below.
Wavelength |
Star Number |
Longest peak wavelength |
|
↓ |
|
↓ |
|
↓ |
|
↓ |
|
↓ |
|
Shortest peak wavelength |
|
|
Explore 5. Now, use the inverse relationship between continuum
peak wavelength and temperature to rank the stars according to temperature.
Temperature |
Star Number |
Spectral Type |
Hottest |
|
|
↓ |
|
|
↓ |
|
|
↓ |
|
|
↓ |
|
|
↓ |
|
|
Coolest |
|
|
I would like to let the students discover the OBAFGKM ordering for themselves, but this may not be viable. Can I do without this paragraph?
Astronomers classify stars according to temperature with the hottest stars designated as 'O' stars, the next hottest stars
as 'B' stars, the next hottest 'A' and so on, following the scheme O,B,A,F,G,K, and M. The letter assigned to a star is
termed its spectral class. Each of the seven spectra corresponds to one of the classes of stars. In the third column of the
table mark the spectral type that corresponds to each star using the lettering scheme described above.
|
|