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175 lines
6.2 KiB
175 lines
6.2 KiB
<sect1 id="ai-colorandtemp">
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<sect1info>
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<author>
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<firstname>Jasem</firstname>
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<surname>Mutlaq</surname>
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<affiliation><address>
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</address></affiliation>
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</author>
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</sect1info>
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<title>Star Colors and Temperatures</title>
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<indexterm><primary>Star Colors and Temperatures</primary>
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<seealso>Blackbody Radiation</seealso>
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<seealso>Magnitude Scale</seealso>
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</indexterm>
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<para>
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Stars appear to be exclusively white at first glance.
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But if we look carefully, we can notice a range of colors: blue,
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white, red, and even gold. In the winter constellation of Orion, a
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beautiful contrast is seen between the red Betelgeuse at Orion's
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"armpit" and the blue Bellatrix at the shoulder. What causes stars to
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exhibit different colors remained a mystery until two centuries ago,
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when Physicists gained enough understanding of the nature of light and
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the properties of matter at immensely high temperatures.
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</para>
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<para>
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Specifically, it was the physics of
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<link linkend="ai-blackbody">blackbody radiation</link> that enabled
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us to understand the variation of stellar colors. Shortly after
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blackbody radiation was understood, it was noticed that the spectra of
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stars look extremely similar to blackbody radiation curves of
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various temperatures, ranging from a few thousand Kelvin to ~50,000
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Kelvin. The obvious conclusion is that stars are similar to
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blackbodies, and that the color variation of stars is a direct
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consequence of their surface temperatures.
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</para>
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<para>
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Cool stars (i.e., Spectral Type K and M) radiate most
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of their energy in the red and infrared region of the
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electromagnetic spectrum and thus appear red, while hot stars (i.e.,
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Spectral Type O and B) emit mostly at blue and ultra-violet
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wavelengths, making them appear blue or white.
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</para>
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<para>
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To estimate the surface temperature of a star, we can use the known
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relationship between the temperature of a blackbody, and the
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wavelength of light where its spectrum peaks. That is, as you
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increase the temperature of a blackbody, the peak of its spectrum
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moves to shorter (bluer) wavelengths of light.
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This is illustrated in Figure 1 where the intensity of three
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hypothetical stars is plotted against wavelength. The "rainbow"
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indicates the range of wavelengths that are visible to the human eye.
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</para>
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<para>
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<mediaobject>
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<imageobject>
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<imagedata fileref="star_colors.png" format="PNG"/>
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</imageobject>
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<caption><para><phrase>Figure 1</phrase></para></caption>
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</mediaobject>
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</para>
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<para>
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This simple method is conceptually correct, but it cannot be used to
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obtain stellar temperatures accurately, because stars are
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<emphasis>not</emphasis> perfect blackbodies. The presence of various
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elements in the star's atmosphere will cause certain wavelengths of
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light to be absorbed. Because these absorption lines are not uniformly
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distributed over the spectrum, they can skew the position of
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the spectral peak.
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Moreover, obtaining a usable spectrum of a star
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is a time-intensive process and is prohibitively inefficient for large
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samples of stars.
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</para>
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<para>
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An alternative method utilizes photometry to measure the intensity of
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light
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passing through different filters. Each filter allows
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<emphasis>only</emphasis> a specific part of the spectrum
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of light to pass through while rejecting all others. A widely used
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photometric system is called the <firstterm>Johnson UBV
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system</firstterm>. It employs three bandpass filters: U
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("Ultra-violet"), B ("Blue"), and V ("Visible"); each occupying different regions of the
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electromagnetic spectrum.
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</para>
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<para>
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The process of UBV photometry involves using light sensitive devices
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(such as film or CCD cameras) and aiming a telescope at a star to
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measure the intensity of light that passes through each of the
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filters individually. This procedure gives three apparent
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brightnesses or <link linkend="ai-flux">fluxes</link> (amount of
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energy per cm^2 per second) designated by Fu, Fb, and Fv. The ratio of
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fluxes Fu/Fb and Fb/Fv is a quantitative measure of the star's
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"color", and these ratios can be used to establish a temperature scale
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for stars. Generally speaking, the larger the Fu/Fb and Fb/Fv ratios
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of a star, the hotter its surface temperature.
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</para>
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<para>
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For example, the star Bellatrix in Orion has Fb/Fv = 1.22, indicating
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that it is brighter through the B filter than through the V filter.
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furthermore, its Fu/Fb ratio is 2.22, so it is brightest through the U
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filter. This indicates that the star must be very hot indeed, since
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the position of its spectral peak must be somewhere in the range of
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the U filter, or at an even shorter wavelength. The surface
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temperature of Bellatrix (as determined from comparing its spectrum to
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detailed models that account for its absorption lines) is about 25,000
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Kelvin.
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</para>
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<para>
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We can repeat this analysis for the star Betelgeuse. Its Fb/Fv and
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Fu/Fb ratios are 0.15 and 0.18, respectively, so it is brightest
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in V and dimmest in U. So, the spectral peak of Betelgeuse must be
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somewhere in the range of the V filter, or at an even longer
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wavelength. The surface temperature of Betelgeuse is only 2,400
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Kelvin.
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</para>
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<para>
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Astronomers prefer to express star colors in terms of a difference in
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<link linkend="ai-magnitude">magnitudes</link>, rather than a ratio of
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<link linkend="ai-flux">fluxes</link>. Therefore, going back to blue
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Bellatrix we have a color index equal to
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</para>
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<para>
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B - V = -2.5 log (Fb/Fv) = -2.5 log (1.22) = -0.22,
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</para>
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<para>
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Similarly, the color index for red Betelgeuse is
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</para>
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<para>
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B - V = -2.5 log (Fb/Fv) = -2.5 log (0.18) = 1.85
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</para>
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<para>
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The color indices, like the <link linkend="ai-magnitude">magnitude
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scale</link>, run backward. <emphasis>Hot and blue</emphasis>
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stars have <emphasis>smaller and negative</emphasis> values of B-V
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than the cooler and redder stars.
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</para>
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<para>
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An Astronomer can then use the color indices for a star, after
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correcting for reddening and interstellar extinction, to obtain an accurate temperature of that star.
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The relationship between B-V and temperature is illustrated in Figure
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2.
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</para>
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<para>
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<mediaobject>
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<imageobject>
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<imagedata fileref="color_indices.png" />
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</imageobject>
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<caption><para><phrase>Figure 2</phrase></para></caption>
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</mediaobject>
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</para>
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<para>
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The Sun with surface temperature of 5,800 K has a B-V index of 0.62.
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</para>
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</sect1>
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