1. The Stars: A Celestial Census
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2. What’s a census? What’s it for?
Stellar Questions
What’s a census?
What’s it for?
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3. The Lives of Stars
Stars live for a very long time, up to 100 million years or more
No humans can possibly observe a star this long!
How can we learn about the stages in a star’s life?
We can take a celestial census, getting a snapshot of many stars at different stages of their life
We can then try to infer the stages that a star goes through from the data we assemble in the census
But we can be misled if the star sample in the census is biased (as in political surveys)
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4. A Stellar Census (1) We measure distances in light years (LY)
Astronomical distances are difficult to measure, to be discussed in Ch. 18
Small stars are less luminous and, therefore, harder to see
If not corrected for these hard-to-see stars, our sample of stars will be biased
Careful observation reveals that small stars (brown dwarfs) are more common than large stars
While less numerous, large stars are easier to see at large distances
Most of the stars visible to the naked eye are large
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5. A Stellar Census (2)
Stars that appear very bright are not necessarily very close to us, and those appearing faint are not necessarily very distant from us
In fact, the brightest stars are bright mainly because they are intrinsically very luminous
Most of them are very far away
Moreover, most of the nearest stars are intrinsically very faint
The luminosity (L) of stars ranges from more than 106 LSun for the most luminous stars to 10-6 LSun for brown dwarfs
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6. Measuring Stellar Masses
Mass is one of a star’s most important characteristics
Knowing the mass can help us estimate how long it will shine and what its ultimate fate will be
Yet, a star’s mass is very difficult to measure directly
Indirect measurements of stellar masses can be done for binary-star systems
Each system consists of two stars that orbit each other, bound together by gravity
Strictly speaking, each of the binary stars orbits a common point called the center of mass
Animation
About half of stars are binary stars

7. Orbits and Masses of Binary Stars
The masses of the 2 stars can be estimated using Kepler's third law
The orbital period P (in years) and semimajor axis D (in AU) of the ellipse are related to the masses M1 and M2 (in units of the Sun’s mass) by D3 = (M1+M2) P2 
Thus, if D and P are measured, the sum of the masses can be found
If the relative orbital speeds of the 2 stars are also measured, the mass of each star separately can be calculated as well D
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8. Visual Binaries
Binary-star systems in which both of the stars can be seen with a telescope are called visual binaries
Animation
Binary stars: Sirius A and B
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9. Sirius A and B Sirius A is normal star
Sirius B is a white dwarf companion
The orbits are drawn to scale, but the sizes of the stars are exaggerated
Sirius A is considerably larger than the Sun, while Sirius B is about the size of the Earth
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10. Spectroscopic Binaries
In some binary-star systems, only one of the stars can be seen with a telescope, but the presence of the companion star is revealed by spectroscopy
Such stars are called spectroscopic binaries
The binary nature is indicated in the periodic Doppler-shift of their spectral lines as they orbit around each other
Animation

11. Doppler Effect in Binary Stars
If the line spectra of the spectroscopic binaries can be observed, their motion is reflected in the Doppler shifts of the spectral lines
Radial velocities of spectroscopic binaries
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12. Range of Stellar Masses
How large and small can stars’ masses be?
Stars with masses up to about 100 times that of the Sun have been discovered
Some may have masses up to about 200 solar masses
Theoretical calculations suggest that the mass of a true star must be at least 1/12 that of the Sun
A “true” star is one that becomes hot enough to fuse protons to form helium (see Ch. 15)
Objects with masses between 1/100 and 1/12 that of the Sun are called brown dwarfs
They may produce energy for a brief time by nuclear reactions, but do not become hot enough to fuse protons
They are intermediate in mass between stars and planets
Objects with masses less than about 1/100 that of the Sun are considered planets
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13. Mass-Luminosity Relation
There is a correlation between the mass and luminosity of a star
The more massive stars are generally also the more luminous (they give off more energy)
For about 10% of the stars, this relationship is violated
They include the white dwarfs
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14. Diameters of Stars
The diameter of a star can be determined by measuring the time it takes an object (the Moon, a planet, or a companion star) to pass in front of it and blocks its light
The blocking of the star’s light is an eclipse
The star’s brightness decreases gradually during the eclipse
The time for the brightness decrease depends on the size of the star
Accurate sizes for a large number of stars come from measurements of eclipsing binaries
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15. Eclipsing Binary System
Some binary stars are lined up in such a way that, when viewed from the Earth, each star passes in front of the other during every revolution
Thus, we can observe periodic eclipses in these binary-star systems, which are therefore called eclipsing binaries
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16. Techniques for Measuring Characteristics of Stars
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17. H-R Diagram
There is a relationship between the temperature (color) and luminosity of 90% of stars
They lie along a band called the main sequence
The plot of stars’ luminosities versus their temperatures is called the Hertzsprung Russell diagram (H-R diagram)
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18. H-R Diagram for Many Stars
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19. Features of H-R Diagram
The main-sequence band contains almost 90% of the stars
Large blue stars
Medium yellow stars
Small red stars
About 10% of the stars lie below the main sequence
They are the hot, but dim, white dwarfs
No more than 1% of the stars lie above the main sequence
They are cool and very luminous
Hence they must be the giants and supergiants
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20. Where would you put a brown dwarf on this diagram?
Stellar Question
Where would you put a brown dwarf on this diagram?
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21. Characteristics of Main-Sequence Stars
The main sequence turns out to be a sequence of stellar masses (for almost 90% of the stars)
The more massive stars have the more weight and can thus compress their centers to the greater degree, which implies that they are the hotter inside and the better at generating energy from nuclear reactions deep within
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22. The Other 10% of Stars Roughly 10% of the stars
do not follow the mass-luminosity relationship
do not lie on the main sequence
Giant and supergiant stars
lie on the upper-right section of the H-R diagram
are very luminous because they are large in diameter, although they are cool
make up less than 1% of the stars
White dwarfs
lie on the lower-left section of the H-R diagram
are small in diameter (similar to Earth’s)
are hot, but dim
make up about 10% of the stars
Betelgeuse
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