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Chapter 9 Remnants of Rock and Ice

Chapter 9 Remnants of Rock and Ice. Asteroids, Comets, and Pluto. 9.1 Asteroids and Meteorites. Our Goals for Learning • Why is there an asteroid belt? • How are meteorites related to asteroids?. Asteroid Facts. Asteroids are rocky leftovers of planet formation.

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Chapter 9 Remnants of Rock and Ice

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  1. Chapter 9Remnants of Rock and Ice Asteroids, Comets, and Pluto

  2. 9.1 Asteroids and Meteorites Our Goals for Learning • Why is there an asteroid belt? • How are meteorites related to asteroids?

  3. Asteroid Facts • Asteroids are rocky leftovers of planet formation. • Largest is Ceres, diameter ~1,000 km • 150,000 in catalogs, and probably over a million with diameter >1 km. • Small asteroids are more common than large asteroids. • All the asteroids in the solar system wouldn’t add up to even a small terrestrial planet.

  4. Asteroids are cratered and not round

  5. Why is there an asteroid belt?

  6. More than 150,000 asteroids at their predicted locations for Jan 1 2004 On this scale, asteroids are much smaller than the dots used to represent them

  7. Why are there very few asteroids beyond Jupiter’s orbit? • There was no rocky material beyond Jupiter’s orbit. • The heaviest rocks sank towards the center of the solar system. • Ice could form in the outer solar system. • A passing star probably stripped away all of those asteroids, even if they were there at one time.

  8. Why are there very few asteroids beyond Jupiter’s orbit? • There was no rocky material beyond Jupiter’s orbit. • The heaviest rocks sank towards the center of the solar system. • Ice could form in the outer solar system. • A passing star probably stripped away all of those asteroids, even if they were there at one time.

  9. Which explanation seems to be the most plausible? • The belt is where all the asteroids happened to form. • The belt is the remnant of a large terrestrial planet that used to be between Mars and Jupiter. • The belt is where all the asteroids happened to survive.

  10. Which explanation seems to be the most plausible? • The belt is where all the asteroids happened to form. • The belt is the remnant of a large terrestrial planet that used to be between Mars and Jupiter. • The belt is where all the asteroids happened to survive. But WHY didn’t they form a little planet?

  11. Rocky planetesimals survived in the asteroid belt between Mars and Jupiter because they did not accrete into a planet. Jupiter’s gravity, stirs up the asteroid orbits and prevents their planet formation.

  12. How are meteorites related to asteroids?

  13. How are meteorites related to asteroids? Meteorites are pieces of asteroids - or sometimes planets or the Moon.

  14. Meteor: The bright tail of hot debris from the rock Meteorite: A rock from space that reaches Earth’s surface

  15. Peekskill, NY: October 9, 1992

  16. Pieces of Asteroids:Meteorite Types • Primitive: Unchanged in composition since they first formed 4.6 billion years ago. • Processed: Younger, have experienced processes like volcanism or differentiation.

  17. Primitive Meteorites: simple, all ingredients mixed together

  18. Processed Meteorites: shattered fragments of larger objects Iron from a core Volcanic rock from a crust or mantle

  19. What do we learn from meteorites? • primitive meteorites tell us when solar system formation began. • Processed meteorites tell us what asteroids are like on the inside. • Processed meteorites provide direct proof that differentiation and volcanism happened on asteroids.

  20. Meteorites from Moon and Mars • A few meteorites arrive from the Moon and Mars • Composition differs from the asteroid fragments. • A cheap (but slow) way to acquire moon rocks and Mars rocks. • One Mars meteorite generated a stir when scientists claimed evidence for microscopic life in it.

  21. • Why is there an asteroid belt? Orbital resonances with Jupiter disrupted the orbits of planetesimals, preventing them from accreting into a planet. Those that were not ejected from this region make up the asteroid belt today. Most asteroids in other regions of the inner solar system accreted into one of the planets. • How are meteorites related to asteroids? Most meteorites are pieces of asteroids. Primitive meteorites are essentially unchanged since the birth of the solar system. Processed meteorites are fragments of larger asteroids that underwent differentiation. What have we learned?

  22. 9.2 Comets • Our Goals for Learning • How do comets get their tails? • Where do comets come from?

  23. How do comets get their tails?

  24. Comet Facts • Formed beyond the frostline, comets are icy counterparts to asteroids. • “Dirty snowballs” = the nucleus • Most comets do not have tails. • Most comets remain perpetually frozen in the outer solar system. Only a few enter the inner solar system, where they can grow tails.

  25. When a comet nears the Sun, its ices can sublimate into gas and carry off dust, creating a coma and long tails.

  26. Draw This Picture

  27. Comets eject small particles that follow the comet around in its orbit This can cause meteor showers when Earth crosses the comet’s orbit.

  28. Meteors in a shower appear to emanate from the same area of sky because of Earth’s motion through space

  29. Where do comets come from?

  30. Only a tiny number of comets enter the inner solar system - most stay far from the Sun Oort cloud: On random orbits extending to about 50,000 AU Kuiper belt: On orderly orbits from 30-100 AU in disk of solar system

  31. How did they get there? • Kuiper belt comets align with the plane of planet orbits • Oort Cloud Comets were kicked out of the solar system by the gravity from jovian planets: random orbits

  32. What have we learned? • How do comets get their tails? • The vast majority of comets do not have tails. Only those few comets that enter the solar system grow tails. As the comet approaches the Sun its nucleus heats up. Some of the comet’s ice sublimates into gas, and the escaping gases carry along some dust. The gas and dust form a coma and two tails: a plasma tail of ionized gas and a dust tail. Larger particles can also escape, becoming the particles that cause meteors and meteor showers on Earth.

  33. What have we learned? • Where do comets come from? • Comets that enter the solar system come from one of two reservoirs in the outer solar system: the Kuiper belt and the Oort cloud. The Kuiper belt comets still reside in the region beyond Neptune in which they formed during the birth of the solar system. The Oort cloud comets are thought to have formed in the region of the jovian planets, and were kicked out to the great distance of the Oort cloud by gravitational encounters with the planets.

  34. 9.3 Pluto: Lone Dog or Part of a Pack? • Our Goals for Learning • What is Pluto like? • Is Pluto a planet or a Kuiper belt comet?

  35. Pluto: the exception • Not a gas giant like the other outer planets. • Has a very elliptical, inclined orbit. • By far the smallest planet, and smaller than several moons. • Has a surprisingly large moon Charon, probably formed by a huge comet collision with Pluto.

  36. Pluto will never collide with Neptune because of a 3:2 orbital resonance.

  37. What is Pluto like? • 1978 discovery of Pluto’s moon Charon: Pluto’s mass from Newton’s orbital law. • It has a thin nitrogen atmosphere that will refreeze onto the surface as Pluto’s orbit takes it farther from the Sun. • Pluto is the largest Solar System object that has not been visited by spacecraft.

  38. HST’s view of Pluto & Charon

  39. Brightness variations during eclipsing orbits showed dirty ice - like comets.

  40. Is Pluto a planet or a Kuiper Belt comet?

  41. Is Pluto a planet or a Kuiper Belt comet? • Pluto is well beyond Neptune, in the Kuiper Belt. • Inclined orbit is typical of Kuiper Belt comets. • Composition is typical of Kuiper Belt comets, but not any of the other planets.

  42. Is Pluto a planet or a Kuiper Belt comet? • Kuiper Belt objects have been found that approach Pluto’s size. • Kuiper Belt comets have similar orbital resonances with Neptune. • Kuiper Belt comets can have moons. • Triton (a captured moon) is even larger than Pluto.

  43. • What is Pluto like? Pluto is much smaller than any other planet, with an orbit more elliptical and more inclined to the ecliptic plane than that of any other planet. It is made mostly of ices and has a very thin atmosphere of gases that are expected to freeze onto the surface as Pluto moves farther from the Sun in its 248-year orbit. It has a moon, Charon, with a slightly lower density than Pluto, suggesting that Charon may have been formed in a giant impact. • Is Pluto a planet or a Kuiper belt comet? Whether Pluto should be called a “planet” is a matter of opinion, but its properties suggest that it is a Kuiper belt comet. Its composition and orbital properties match those of other Kuiper belt comets and do not fit in with the other planets. It is the largest known Kuiper belt comet today, but there may be larger ones still awaiting discovery. What have we learned?

  44. 9.4 Cosmic Collisions: small bodies vs. the planets Our Goals for Learning • Have we ever witnessed a major impact? • Did an impact kill the dinosaurs? • Is the impact threat a real danger or just media hype? • How do other planets affect impact rates and life on Earth?

  45. Have we ever witnessed a major impact?

  46. Comet SL9 caused a string of violent impacts on Jupiter in 1994, reminding us that catastrophic collisions still happen. Tidal forces tore it apart during previous encounter with Jupiter

  47. Impact plume rises high above Jupiter’s surface

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