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Astronomy190 - Topics in Astronomy

Astronomy190 - Topics in Astronomy. Astronomy and Astrobiology Lecture 4 : Astronomy Basics Ty Robinson. Questions of the Day. What does it mean to say that we are made of star stuff ? What are Kepler’s three laws? What is spectroscopy and how does it help us to learn about the Universe?.

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Astronomy190 - Topics in Astronomy

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  1. Astronomy190 - Topics in Astronomy Astronomy and Astrobiology Lecture 4 : Astronomy Basics Ty Robinson

  2. Questions of the Day • What does it mean to say that we are made of star stuff? • What are Kepler’s three laws? • What is spectroscopy and how does it help us to learn about the Universe?

  3. Copernican Revolution Earth is not at the center of the Universe. Nikolaus Copernicus (1473-1543)

  4. 100,000 light years ~300 billion stars speed of light = 180,000 miles/second

  5. Question There are roughly 100 billion (=1x1011) galaxies in the observable Universe. If there are about 300 billion (=3x1011) stars in every galaxy, how many stars are there in the observable Universe? 4x1011 3x1022 3x1011 infinite Answer: 3x1022 stars = 30 billion trillion What if each star has one Earth-like planet?

  6. Composition of the Interstellar Material

  7. Orion Nebula ~3 light years ~3,000 stars 10-2 light years

  8. Star Cluster ~2 light years Question The stars in this cluster are all at the same distance from Earth. What are two key features of stars that we can deduce from looking at the stars in this image?

  9. Hertzsprung-Russell (HR) Diagram Luminosity Color (type) Mass Size Lifetime

  10. Question If it takes about 1 billion (=109) years for simple life to originate and flourish on a planet, what types of stars (OBAFGKM) are good places to search for life? all stars OBA G FGKM

  11. Low Mass (FGKM) Stars E=mc2

  12. All good things must come to an end…

  13. Planetary Nebula ~1 light year Question If this were the whole picture, would we be here today? Why?

  14. High Mass (OBA) Stars Question If this were the whole picture, would we be here today? Why? Note: Nitrogen is a product of Helium fusion.

  15. Supernova The energy released during a supernova is equal to the entire energy that the Sun will release in its entire life!

  16. Planet Formation AU = average Earth-Sun separation Jupiter’s Orbit dust planetesimal boulder asteroid 10-6 m 1 m 104 m 106 m

  17. Terrestrial Planet Formation Circularity Star-Planet Distance [AU]

  18. Giant Planet Formation Beyond the frost line, planetesimals can grow from rock and ice. This leads to the formation of “planetary cores”, which are rocky/icy planetesimals around 10x as massive as Earth. These cores are so massive that they accrete gas, forming gas giant planets.

  19. Questions Where is the frost line in our Solar System? Between Earth and Mars? Between Neptune and Pluto? Mercury Venus Earth Mars Jupiter Saturn Uranus Neptune Pluto Is frost line around an M-dwarf at the same distance as the frost line around the Sun?

  20. 1 - Bodies orbit their parent star on elliptical orbits with the star at one focus of the orbit. Kepler’s Laws 2 - In an orbit, the closer a body is to its parent star the faster it moves.

  21. 3 - The orbital period (P) of a body is related to the body’s average distance from its parent star (a) by the equation P2 = a3 (with P measured in years and a in AU). Kepler’s Laws Bottom Line: Close-in planets have shorter orbital periods!

  22. Electromagnetic Spectrum

  23. Emission and Absorption Spectra • Whether the spectrum is continuous, or in emission or absorption tells us about the composition and temperature structure of the object we are studying.

  24. CO2 CO2 Water CO2

  25. Questions of the Day • What does it mean to say that we are made of star stuff? • What are Kepler’s three laws? • What is spectroscopy and how does it help us to learn about the Universe?

  26. Quiz 1 - Explain two reasons why we limit our search for habitable planets to worlds around low-mass, main sequence stars. 2 - What three characteristics must a world have in order to be considered habitable? 3 - What is one thing you did not understand from today’s lecture?

  27. A Multitude of Worlds • 353 Planets • 298 Planetary Systems • 38 Multiple Planet Systems Over 92% of the planets discovered to date were found using the Radial Velocity (Doppler) technique. As of 7/21/09

  28. Summary 1 - The Universe is a huge place and contains billions of trillions of stars (at least!). 2 - The life cycles of high-mass and low-mass stars are necessary for the production and distribution of the chemical elements of which life is made. 3 - Kepler’s Three Laws - orbits are ellipses - closer = faster - P2 = a3 4 - Extrasolar planets are detected by - radial velocity (indirect) - transit (indirect) - imaging (direct)

  29. Extrasolar Planets - Doppler Technique The sound is at a higher pitch (smaller wavelength) as the car approaches and at a lower pitch (longer wavelength) as it recedes. The light waves are at a longer wavelength (redder) as the star moves away from you and at a shorter wavelength (bluer) as the star approaches you.

  30. Extrasolar Planets - Doppler Technique Question How can we determine the planet-star separation?

  31. Extrasolar Planets - Transit Technique We learn the size, mass and density of the planet!

  32. Extrasolar Planets - Direct Detection Orbit of Neptune 120 AU Mass of Neptune? Jupiter?

  33. Question Why are there so many close-in, Jupiter-mass planets?

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