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LECTURE 21, NOVEMBER 16, 2010

LECTURE 21, NOVEMBER 16, 2010. ASTR 101, SECTION 3 INSTRUCTOR, JACK BRANDT jcbrandt@unm.edu. Question 3. a) measuring distances with Cepheid variable stars. b) identifying the mass of the Galaxy’s central black hole. c) determining the masses of stars in an eclipsing binary system.

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LECTURE 21, NOVEMBER 16, 2010

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  1. LECTURE 21, NOVEMBER 16, 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. ASTR 101-3, FALL 2010

  6. ASTR 101-3, FALL 2010

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  9. ASTR 101-3, FALL 2010

  10. Question 3 a) measuring distances with Cepheid variable stars. b) identifying the mass of the Galaxy’s central black hole. c) determining the masses of stars in an eclipsing binary system. d) using spectroscopic parallax to measure distances to stars. The period – luminosity relationship is a crucial component of

  11. Question 3 a) measuring distances with Cepheid variable stars. b) identifying the mass of the Galaxy’s central black hole. c) determining the masses of stars in an eclipsing binary system. d) using spectroscopic parallax to measure distances to stars. The period – luminosity relationship is a crucial component of Cepheid variable stars with longer periods have higher actual luminosities; short-period Cepheids are dimmer.

  12. ASTR 101-2, SPRING 2006

  13. ASTR 101-3, FALL 2010

  14. ASTR 101-3, FALL 2010

  15. Question 1 a) supernova remnants. b) white dwarf stars in the spiral arms. c) red giant variable stars in globular clusters. d) bright O and B stars in open clusters. e) X-ray sources. The location of the galactic center was identified using

  16. Question 1 a) supernova remnants. b) white dwarf stars in the spiral arms. c) red giant variable stars in globular clusters. d) bright O and B stars in open clusters. e) X-ray sources. The location of the galactic center was identified using Harlow Shapley used pulsating RR-Lyrae variables as distance indicators to the globular clusters. He then deduced the distance and direction of the Milky Way’s center.

  17. ASTR 101-3, FALL 2010

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  22. Question 7 a) the spiral arms formed first. b) the globular clusters formed first. c) the disk component started out thin and grew. d) spiral density waves formed first. e) the bar in the bulge formed first. In the formation of our Galaxy

  23. Question 7 a) the spiral arms formed first. b) the globular clusters formed first. c) the disk component started out thin and grew. d) spiral density waves formed first. e) the bar in the bulge formed first. In the formation of our Galaxy Globular clusters contain very old stars, no gas or dust, and orbit around the center randomly.

  24. ASTR 101-3, FALL 2010

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  26. Question 5 a) a spiral galaxy. b) a barred spiral galaxy. c) an elliptical galaxy. d) a quasar. e) an irregular galaxy. Detailed measurements of the disk suggest that our Milky Way is

  27. Question 5 a) a spiral galaxy. b) a barred spiral galaxy. c) an elliptical galaxy. d) a quasar. e) an irregular galaxy. Detailed measurements of the disk suggest that our Milky Way is Measurements of stellar motion in and near the bulge imply that it is football shaped, about half as wide as it is long, characteristic of a barred spiral galaxy.

  28. ASTR 101-3, FALL 2010

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  32. ASTR 101-2, SPRING 2006

  33. ASTR 101-3, FALL 2010

  34. Question 6 a) the Sun’s mass and velocity in orbit around the galactic center b) the rotation of the bulge and disk components c) the Sun’s age and age of globular cluster stars d) the motion of spiral arms and the mass of the central black hole e) the Sun’s orbital period and distance from the center What two observations allow us to estimate the Galaxy’s mass?

  35. Question 6 a) the Sun’s mass and velocity in orbit around the galactic center b) the rotation of the bulge and disk components c) the Sun’s age and age of the globular cluster stars d) the motion of spiral arms and mass of the central black hole e) the Sun’s orbital period and distance from the center What two observations allow us to estimate the Galaxy’s mass? Use the modified form of Kepler’s law to find the mass: Total mass = (orbital size)3 / (orbital period)2

  36. Question 10 a) 21-cm maps of the spiral arms b) the rotation curve of the outer edges of the Galaxy c) orbits of open clusters in the disk d) infrared observations of new star- forming regions e) X-ray images of other galaxies What suggests that the mass of our Galaxy extends farther than its visible disk?

  37. Question 10 a) 21-cm maps of the spiral arms b) the rotation curve of the outer edges of the Galaxy c) orbits of open clusters in the disk d) infrared observations of new star- forming regions e) X-ray images of other galaxies What suggests that the mass of our Galaxy extends farther than its visible disk? The outer edges of the Galaxy’s disk rotate much faster than they should. Most of the mass of the Galaxy must be dark matter.

  38. ASTR 101-3, FALL 2010

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  42. Question 4 High-speed motion of gas and stars near the Milky Way Galaxy’s center is explained by a) tidal forces from the Andromeda Galaxy. b) accretion disks around neutron stars. c) gamma-ray bursts. d) gravitation from globular clusters. e) a supermassive black hole.

  43. Question 4 High-speed motion of gas and stars near the Milky Way Galaxy’s center is explained by a) tidal forces from the Andromeda Galaxy. b) accretion disks around neutron stars. c) gamma-ray bursts. d) gravitation from globular clusters. e) a supermassive black hole. Recent observations estimate the black hole to be 4 million solar masses.

  44. ASTR 101-3, FALL 2010

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