The Nature of Galaxies

1. The Nature of Galaxies Chapter 17

2. Elliptical Other Galaxies • External to Milky Way • established by Edwin Hubble • used Cepheid variables to measure distance • M31 (Andromeda Galaxy) far outside Milky Way • Three basic types: • elliptical • spiral • irregular Spiral Irregular

3. Spiral Galaxies • Similar to Milky Way: • thin disk + nuclear bulge + halo • Disk contains: • dust and gas • H II regions, H I regions, molecular clouds • spiral arms • active star formation • open clusters • mixture of young & old stars • Halo contains: • old stars • Globular Clusters • Bulge contains: • old stars

4. Spiral Galaxies

5. Barred Spiral Galaxies • Some spirals have bar in center • “barred spirals”

6. Elliptical Galaxies • Shape ranges from: • spherical to ellipsoidal • Characteristics: • no disk or spiral arms • old reddish stars • similar to halo or bulge in spirals • little gas or dust • little star formation

7. Irregular Galaxies • No specific shape • often appear chaotic • Often have intense star formation • gravitational interaction with other galaxies? • Mixture of old and new stars

8. Interacting Galaxies

9. Cartwheel Galaxy NASA/HST Simulation by C. Mihos et al., CWRU

10. Galaxy Masses • For spirals: • use Doppler shift; measure galaxy rotation • make rotation curve • calculate mass using Kepler’s Law • For ellipticals: • use Doppler shift; measure stellar orbital velocities • calculate mass using Kepler’s Law • Results • Giant ellipticals and spirals are most massive; • irregulars & dwarf ellipticals least massive

11. Mass-to-Light Ratios • ratio of mass to luminosity • for Sun, • M/L = 1 • average star • M/L = 2 to 3 • for entire Galaxy • M/L ~ 100 • 90% of galaxy mass is unseen

12. Extragalactic Distances • Compare apparent and absolute brightness • Variable Stars: • Cepheids, RR Lyrae • Standard Candles: • brightest stars, supernovae, planetary nebulae • Galaxy techniques: • For spirals: • rotation rate gives mass • mass depends on number of stars, hence luminosity • For ellipticals: • range of stellar velocities depends on mass (hence luminosity)

13. Fifteen years ago, a quasar was observed that was found to be located 8 billion light years away. If our universe is approximately • 15 billion years old, when did the quasar emit the light that we observe? • 15 years ago • 7 billion years ago • 8 billion years ago • 15 billion years ago

14. Galaxy Motion • Galaxy spectra: • absorption lines redshifted • more distant galaxies have larger redshift • ALL galaxies moving away

15. The Hubble Law • Hubble Law: • The more distant the galaxy, the faster it is moving away.v = H d (H is the Hubble constant, d is distance)

16. Implications of Hubble Law • Every galaxy moving away • Farther away = faster • Conclusion: • Universe is expanding • Predicted by Einstein’s Theory of Relativity • Are we at center? NO • universe same in all directions • there is no center!

17. The Expanding Universe • A uniformly expanding universe • explains Hubble law • example: expanding loaf of raisin bread • Galaxies (like raisins) not moving, not expanding • Space is expanding