Oort Cloud, Kuiper Belt, Comets, and Asteroids

1. Oort Cloud, Kuiper Belt, Comets, and Asteroids • Origin of the Kuiper Belt • KBO’s up close (sort of) • The Pluto Affair… • Short period vs Long Period comets; origin in Kuiper Belt vs Oort Cloud • The Asteroid Belt and its origin

2. The Oort Cloud • Inferred by Jan Oort in the mid 20th Century, because there were so many comets on orbits with periods of thousands of years. • Kepler’s Laws imply outer end of orbit as far as half a light year away • This is about the tidal limit which would bind material to the sun vs the rest of the Galaxy, so it makes sense. • We cannot directly image anything in the Oort Cloud. Way too far away and dim to every hope to see. • Little angular momentum in this material, so not flattened like a disk as we see closer in to the sun. So, called the Oort “Cloud”, not the Oort “Belt”.

4. Beyond Neptune – cold and dark! • No planets beyond Neptune, instead, the Kuiper Belt of large comets… • “rocks” of light elements (hydrogen, oxygen, nitrogen, carbon, chlorine…) are called “ice” and melt at very low temperatures. • Globs of this stuff, mixed with plenty of dust and dirt, are called “Comets”!

5. Why did we kick Pluto out of the Planet Club? • Several reasons: • 1st – it has a highly inclined and elliptical orbit which crosses Neptune: an orbit like a comet, not a planet. • 2nd – it’s one of thousands of small objects out there; a new class of objects – the Kuiper Belt Objects or KBO’s - we didn’t know about till the 1990’s. Pluto was discovered in 1930. • 3rd – it’s mass….. Check this diagram out…

6. Pluto changing mass estimates

7. Triton – the only KBO photographed up close

8. KBO’s

9. Sedna, quaoar, pluto, earth/moon

10. Eris (aka 2003 UB313) – new “King of the Kuiper Belt”

11. Eris orbit

12. Collisions between Kuiper Belt Objects Now Thought to be the Main Source of Short-Period Comets • Simulations show that at the relative velocities KBO’s experience, that the pieces from collisions would result in many losing angular momentum and falling in on the highly elliptical orbits that short-period comets have. • Short period comets – a few miles across, not a few hundred miles across • Highly elliptical orbits falling deep in towards the sun, where sunlight makes them easy to see (and fun to watch!) • And also, easier for spacecraft to visit and photograph up-close

13. C/Wild closeup/ composite

14. C/Borrelly closeup

15. Halley closeup

16. Comet surface - artist

17. Mission: “Deep Impact” – colliding a boulder of copper with a comet

18. Deep Impact before/after

19. What did we Learn about C/Temple I? • The material excavated by the impact material contained more dust and less ice than had been expected. • Ruled out: Comet models of very porous material which had comets as loose aggregates. • The material was finer than expected; scientists compared it to talcum powder rather than sand. Other materials found included clays, carbonates, and sodium, and crystalline silicates which were found by studying the spectroscopy of the impact. • Clays and carbonates usually require liquid water to form and sodium is rare in space. • Comet Temple I was about 75% empty space, similar to a snow bank.

20. Comets – A Tale of Two Tails • Comets swing by the sun on big arcing orbits. • The gas is blown back rapidly, since gas atoms are very light. Gas tail is very straight and moves very fast – gas atoms left comet very recently. • Dust tail is yellowish and often curved, as the dust grains move very slowly, showing the history of the comets path over a longer history.

21. Hyakutake fisheye

22. Hyakutake long fl lens

23. K4 LINEAR; longer exposure

24. C/Machholz

25. C/Hale-Bopp

26. C/Hale-Bopp Jtree

27. C/Bradfield & LINEAR T7

28. C/IkeyaZhang and M31

29. holmes

30. Comets Don’t Live Forever… • Short period comets will lose surface on each passage around the sun • Halley’s comet estimated to lose 3 feet of surface depth on each orbit • In recent years we’ve seen several comets dissintegrate and melt away…

31. C/NEAR with SOHO

32. Comet P57 breaking up

33. S4 LINEAR breaking up

34. S4 LINEAR breakup b&w

35. S4 LINEAR up close

36. S4 LINEAR4

37. S4 pieces

38. SL9 string of comets

39. Crater chain on moon

40. Dust, rocks, are set free during this melting process • These remain in the orbit of the comet, but drift either ahead or behind the main comet as time goes on, and also spreading laterally up to several million miles away from the comet’s orbit path • If this torus of material crosses the Earth’s orbit, we see a meteor shower for a few hours or a few days

41. Uniform vs Leonid meteor streams

42. Comet Temple-Tuttle; parent of the Leonids

43. Leonids ’99 Ayers antiradiant

44. Leonids ‘01

45. Leonids ’01 fisheye

46. Leonids ’01 fisheye2

47. Leonids ‘02

48. Leonids Jtree

49. Leonids ’02 anti radiant

50. Leonids ‘02, lake moon