JasemMutlaqStar Colors and TemperaturesStar Colors and TemperaturesBlackbody RadiationMagnitude Scale
Stars appear to be exclusively white at first glance.
But if we look carefully, we can notice a range of colors: blue,
white, red, and even gold. In the winter constellation of Orion, a
beautiful contrast is seen between the red Betelgeuse at Orion's
"armpit" and the blue Bellatrix at the shoulder. What causes stars to
exhibit different colors remained a mystery until two centuries ago,
when Physicists gained enough understanding of the nature of light and
the properties of matter at immensely high temperatures.
Specifically, it was the physics of
blackbody radiation that enabled
us to understand the variation of stellar colors. Shortly after
blackbody radiation was understood, it was noticed that the spectra of
stars look extremely similar to blackbody radiation curves of
various temperatures, ranging from a few thousand Kelvin to ~50,000
Kelvin. The obvious conclusion is that stars are similar to
blackbodies, and that the color variation of stars is a direct
consequence of their surface temperatures.
Cool stars (i.e., Spectral Type K and M) radiate most
of their energy in the red and infrared region of the
electromagnetic spectrum and thus appear red, while hot stars (i.e.,
Spectral Type O and B) emit mostly at blue and ultra-violet
wavelengths, making them appear blue or white.
To estimate the surface temperature of a star, we can use the known
relationship between the temperature of a blackbody, and the
wavelength of light where its spectrum peaks. That is, as you
increase the temperature of a blackbody, the peak of its spectrum
moves to shorter (bluer) wavelengths of light.
This is illustrated in Figure 1 where the intensity of three
hypothetical stars is plotted against wavelength. The "rainbow"
indicates the range of wavelengths that are visible to the human eye.
Figure 1
This simple method is conceptually correct, but it cannot be used to
obtain stellar temperatures accurately, because stars are
not perfect blackbodies. The presence of various
elements in the star's atmosphere will cause certain wavelengths of
light to be absorbed. Because these absorption lines are not uniformly
distributed over the spectrum, they can skew the position of
the spectral peak.
Moreover, obtaining a usable spectrum of a star
is a time-intensive process and is prohibitively inefficient for large
samples of stars.
An alternative method utilizes photometry to measure the intensity of
light
passing through different filters. Each filter allows
only a specific part of the spectrum
of light to pass through while rejecting all others. A widely used
photometric system is called the Johnson UBV
system. It employs three bandpass filters: U
("Ultra-violet"), B ("Blue"), and V ("Visible"); each occupying different regions of the
electromagnetic spectrum.
The process of UBV photometry involves using light sensitive devices
(such as film or CCD cameras) and aiming a telescope at a star to
measure the intensity of light that passes through each of the
filters individually. This procedure gives three apparent
brightnesses or fluxes (amount of
energy per cm^2 per second) designated by Fu, Fb, and Fv. The ratio of
fluxes Fu/Fb and Fb/Fv is a quantitative measure of the star's
"color", and these ratios can be used to establish a temperature scale
for stars. Generally speaking, the larger the Fu/Fb and Fb/Fv ratios
of a star, the hotter its surface temperature.
For example, the star Bellatrix in Orion has Fb/Fv = 1.22, indicating
that it is brighter through the B filter than through the V filter.
furthermore, its Fu/Fb ratio is 2.22, so it is brightest through the U
filter. This indicates that the star must be very hot indeed, since
the position of its spectral peak must be somewhere in the range of
the U filter, or at an even shorter wavelength. The surface
temperature of Bellatrix (as determined from comparing its spectrum to
detailed models that account for its absorption lines) is about 25,000
Kelvin.
We can repeat this analysis for the star Betelgeuse. Its Fb/Fv and
Fu/Fb ratios are 0.15 and 0.18, respectively, so it is brightest
in V and dimmest in U. So, the spectral peak of Betelgeuse must be
somewhere in the range of the V filter, or at an even longer
wavelength. The surface temperature of Betelgeuse is only 2,400
Kelvin.
Astronomers prefer to express star colors in terms of a difference in
magnitudes, rather than a ratio of
fluxes. Therefore, going back to blue
Bellatrix we have a color index equal to
B - V = -2.5 log (Fb/Fv) = -2.5 log (1.22) = -0.22,
Similarly, the color index for red Betelgeuse is
B - V = -2.5 log (Fb/Fv) = -2.5 log (0.18) = 1.85
The color indices, like the magnitude
scale, run backward. Hot and blue
stars have smaller and negative values of B-V
than the cooler and redder stars.
An Astronomer can then use the color indices for a star, after
correcting for reddening and interstellar extinction, to obtain an accurate temperature of that star.
The relationship between B-V and temperature is illustrated in Figure
2.
Figure 2
The Sun with surface temperature of 5,800 K has a B-V index of 0.62.