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The Family of Stars

0. The Family of Stars. Chapter 9. 0. The Properties of Stars. We already know how to determine a star’s. surface temperature. chemical composition. In this chapter, we will learn how we can determine its. distance. luminosity. radius. mass.

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The Family of Stars

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  1. 0 The Family of Stars Chapter 9

  2. 0 The Properties of Stars We already know how to determine a star’s • surface temperature • chemical composition In this chapter, we will learn how we can determine its • distance • luminosity • radius • mass and how all the different types of stars make up the big family of stars.

  3. 0 Distances to Stars d in parsec (pc) p in arc seconds __ 1 d = p Trigonometric Parallax: Star appears slightly shifted from different positions of the Earth on its orbit 1 pc = 3.26 LY The farther away the star is (larger d), the smaller the parallax angle p.

  4. 0 The Trigonometric Parallax Example: Nearest star, a Centauri, has a parallax of p = 0.76 arc seconds d = 1/p = 1.3 pc = 4.3 LY With ground-based telescopes, we can measure parallaxes p ≥ 0.02 arc sec => d ≤ 50 pc This method does not work for stars farther away than 50 pc.

  5. 0 Proper Motion Nearby stars also show continuous motions across the sky. These are related to the actual motion of the stars throughout the Milky Way, and are called proper motion.

  6. 0 Intrinsic Brightness/ Absolute Magnitude The more distant a light source is, the fainter it appears.

  7. 0 Intrinsic Brightness / Absolute Magnitude (2) More quantitatively: The flux received from the light is proportional to its intrinsic brightness or luminosity (L) and inversely proportional to the square of the distance (d): L __ F ~ d2 Star A Star B Earth Both stars may appear equally bright, although star A is intrinsically much brighter than star B.

  8. 0 Absolute Magnitude To characterize a star’s intrinsic brightness, define Absolute Magnitude (MV): Absolute Magnitude = Magnitude that a star would have if it were at a distance of 10 pc.

  9. 0 The Distance Modulus If we know a star’s absolute magnitude, we can infer its distance by comparing absolute and apparent magnitudes:

  10. 0 The Size (Radius) of a Star We already know: flux increases with surface temperature (~ T4); hotter stars are brighter. But brightness also increases with size: Star B will be brighter than star A. A B Absolute brightness is proportional to radius squared, L ~ R2 Quantitatively: L = 4 p R2s T4 Surface flux due to a blackbody spectrum Surface area of the star

  11. 0 Organizing the Family of Stars: The Hertzsprung-Russell Diagram We know: Stars have different temperatures, luminosities, sizes. To bring some order into that zoo of different types of stars: organize them in a diagram of

  12. The open star cluster M39 0

  13. Regions of the H-R Diagram

  14. 0 The Hertzsprung-Russell Diagram Most stars are found along the Main Sequence

  15. 0 The Hertzsprung-Russell Diagram (2) Same temperature, but much brighter than Main Sequence stars Stars spend most of their active life time on the Main Sequence (MS).

  16. 0 Betelgeuse Polaris 10,000 times the sun’s radius Rigel 100 times the sun’s radius Sun As large as the sun

  17. 0 Spectral Lines of Giants => Absorption lines in spectra of giants and supergiants are narrower than in main sequence stars => From the line widths, we can estimate the size and luminosity of a star.

  18. 0 Luminosity Classes Ia Bright Supergiants Ia Ib Ib Supergiants II II Bright Giants III III Giants IV Subgiants IV V V Main-Sequence Stars

  19. 0 Example: Luminosity Classes • Our Sun: G2 star on the Main Sequence: • G2V • Polaris: G2 star with Supergiant luminosity: G2Ib

  20. The orbit of a binary star system depends on strength of gravity

  21. Visual Binary

  22. Mizar It’s the first binary star system to be imaged telescopically 88 light years from Earth Both stars are themselves spectroscopic binaries!!

  23. Sirius A and B 8.5 Ly

  24. 0 The Center of Mass center of mass = balance point of the system Both masses equal => center of mass is in the middle, rA = rB

  25. 0 Estimating Stellar Masses RecallKepler’s 3rd Law: Py2 = aAU3 Valid for the Solar system: star with 1 solar mass in the center aAU3 ____ MA + MB = Py2 (MA and MB in units of solar masses)

  26. 0 Examples: Estimating Mass Binary system with period of P = 32 years and separation of a = 16 AU: 163 ____ MA + MB = = 4 solar masses 322

  27. 0 Spectroscopic Binaries Usually, binary separation a can not be measured directly because the stars are too close to each other.

  28. 0 Spectroscopic Binaries (3) Typical sequence of spectra from a spectroscopic binary system Time

  29. 0 Spectroscopic Binaries (2) Doppler shift Measurement of radial velocities Estimate of masses Estimate of separation a

  30. 0 Eclipsing Binaries

  31. 0 The Light Curve of Algol

  32. Every 2.87 days its brightness quickly drops from magnitude 2.1 to 3.4 and then rises again to 2.1 over a period of 10 hours.

  33. 0 Masses of Stars in the Hertzsprung-Russell Diagram The more massive a star is, the brighter it is: L ~ M3.5 High masses Mass High-mass stars have much shorter lives than low-mass stars: Low masses tlife ~ M-2.5 Sun: ~ 10 billion yr. 10 Msun: ~ 30 million yr. 0.1 Msun: ~ 3 trillion yr.

  34. 0 Surveys of Stars Ideal situation for creating a census of the stars: Determine properties of all stars within a certain volume

  35. 0 Surveys of Stars Main Problem for creating such a survey: Fainter stars are hard to observe; we might be biased towards the more luminous stars.

  36. 0 A Census of the Stars Faint, red dwarfs (low mass) are the most common stars. Bright, hot, blue main-sequence stars (high-mass) are very rare. Giants and supergiants are extremely rare.

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