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LECTURE 17, OCTOBER 28, 2010

LECTURE 17, OCTOBER 28, 2010. ASTR 101, SECTION 3 INSTRUCTOR, JACK BRANDT jcbrandt@unm.edu. Question 1. a) there are no stars there. b) stars in that direction are obscured by interstellar gas . c) stars in that direction are obscured by interstellar dust .

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LECTURE 17, OCTOBER 28, 2010

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  1. LECTURE 17, OCTOBER 28, 2010 ASTR 101, SECTION 3 INSTRUCTOR, JACK BRANDT jcbrandt@unm.edu ASTR 101-3, FALL 2010

  2. ASTR 101-3, FALL 2010

  3. ASTR 101-3, FALL 2010

  4. ASTR 101-3, FALL 2010

  5. Question 1 a) there are no stars there. b) stars in that direction are obscured by interstellar gas. c) stars in that direction are obscured by interstellar dust. d) numerous black holes capture all the starlight behind them. Some regions of the Milky Way’s disk appear dark because

  6. Question 1 a) there are no stars there. b) stars in that direction are obscured by interstellar gas. c) stars in that direction are obscured by interstellar dust. d) numerous black holes capture all the starlight behind them. Some regions of the Milky Way’s disk appear dark because Dust grains are about the same size as visible light, and they can scatter or block the shorter wavelengths.

  7. Question 2 When a star’s visible light passes through interstellar dust, the light we see a) is dimmed and reddened. b) appears to twinkle. c) is Doppler shifted. d) turns bluish in color. e) ionizes the dust and creates emission lines.

  8. Question 2 When a star’s visible light passes through interstellar dust, the light we see a) is dimmed and reddened. b) appears to twinkle. c) is Doppler shifted. d) turns bluish in color. e) ionizes the dust and creates emission lines. The same process results in wonderful sunsets, as dust in the air scatters the Sun’s blue light, leaving dimmer, redder light.

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  18. Question 4 a) 90% hydrogen, 9% helium, and 1% heavier elements. b) molecules including water and CO2. c) 50% hydrogen, 50% helium. d) hydrogen, oxygen, and nitrogen. e) 99% hydrogen, and 1% heavier elements. Interstellar gas is composed primarily of

  19. Question 4 a) 90% hydrogen, 9% helium, and 1% heavier elements. b) molecules including water and CO2. c) 50% hydrogen, 50% helium. d) hydrogen, oxygen, and nitrogen. e) 99% hydrogen, and 1% heavier elements. Interstellar gas is composed primarily of The composition of interstellar gas mirrors that of the Sun, stars, and the jovian planets.

  20. Question 6 a) its radio waves pass unaffected through clouds of interstellar dust. b) it arises from cool helium gas present throughout space. c) it can be detected with optical telescopes. d) it is produced by protostars. e) it reveals the structure of new stars. 21-centimeter radiation is important because

  21. Question 6 a) its radio waves pass unaffected through clouds of interstellar dust. b) it arises from cool helium gas present throughout space. c) it can be detected with optical telescopes. d) it is produced by protostars. e) it reveals the structure of new stars. 21-centimeter radiation is important because Cool atomic hydrogen gas produces 21-cm radio radiation as its electron “flips” its direction of spin.

  22. ASTR 101-3, FALL 2010

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  34. Question 12 a) age. b) temperature. c) mass. d) color. e) luminosity. Stars in clusters & associations have about the same

  35. Question 12 a) age. b) temperature. c) mass. d) color. e) luminosity. Stars in clusters & associations have about the same Most of the stars in a cluster form about the same time. Stars in the Omega Centauri globular cluster are estimated to be about 14 billion years old.

  36. Question 13 Objects more massive than our Sun form into stars a) much slower, over billions of years. b) in about the same time. c) much faster, over tens of thousands of years. d) not at all – they are unstable.

  37. Question 13 Objects more massive than our Sun form into stars a) much slower, over billions of years. b) in about the same time. c) much faster, over tens of thousands of years. d) not at all – they are unstable. More mass  faster collapse More mass  faster start of fusion reactions More mass  a hotter, more luminous main sequence star

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