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10Nov2006 Ge/Ay133 More on Jupiter, Neptune, the Kuiper belt, and the early solar system.

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Presentation on theme: "10Nov2006 Ge/Ay133 More on Jupiter, Neptune, the Kuiper belt, and the early solar system."— Presentation transcript:

1 10Nov2006 Ge/Ay133 More on Jupiter, Neptune, the Kuiper belt, and the early solar system.

2 The MMSN – Solid surface density near 1-3 g/cm 2 at Jupiter Simulations suggest that surface densities nearly a factor of ten larger might be needed to form Jupiter in ≤10 7 yr. The problem is even worse for the `ice giants’ Uranus and Neptune if they formed near their current locations. Alternatives?

3 i e a What happens to the Kuiper belt if oligarchs migrate/are ejected? (M iso ~r 3/4, nearly 7 M earth at 40 AU) Petit et al. 1999

4 Gas giants? Depending on dust opacity, cores may spend a long time in the “plateau” phase before runaway gas accretion. Form cores closely spaced in higher density region. Radical idea: Investigate what happens dynamically if one of these closely spaced cores reaches the runaway gas accretion stage first.

5 Step 1: Start with four cores+planetesimal swarm Nebular surface density (    g/cm 2,  Hill radius For  =r -2 and n~5-10r H, get ~equal mass cores (isolation mass), choice of  0 leaves room for planetesimal swarm.

6 Step 1: Start with four cores+planetesimal swarm (pictorially) Initial state, no extensive gas accretion yet, so the cores do not strongly stir the swarm or interact.

7 Neptune crossing 3:22:1 Plutinos classical KBOs scattered KBOs The question is, can we get from this initial condition to now?

8 Step 2: Let one core grow, and dominate gravitationally. Nearby cores can be scattered, eccentricity evolves as Steady state if Protoplanet Planetesimals

9 Thus the planetesimal swarm is key in damping eccentric orbits! Early on, scattered protoplanet dominates, or Time scale for eccentricity damping is: For the default case, the damping time is of order a few to few tens of Myr.

10 Statistically, how often do we go from here… … to here?

11 From whence the Plutinos? If Neptune’s migration is sufficiently `slow’, KBOs can be trapped into orbital resonances that move outward w/planet. Hard to explain i distribution of `classical’ belt with this much movement!

12 From whence the Plutinos? A bit better at later times, but the quantitative results do not match those observed, esp. for the scattered population of KBOs…

13 “Standard case”:

14 What if Jupiter forms in “slot #2”?

15 What happens if you change the number of cores?

16 What if you allow the planetesimal disk to be more massive? Classical belt much too massive and extends too far to reproduce observations…

17 How might you truncate the classical KBO population beyond 40-45 AU? Photoevaporation? Stellar encounter? (Shown here) Ida et al. 2000

18 Need to see more distant objects! 35 deg Ida et al. 2000

19 What happens if you let a second (“Saturn”) core accrete gas? This also really helps with the classical KBO issue beyond 40 AU, and keeps Saturn closer to its position in our S.S.

20 J S From whence the Plutinos? If Neptune’s migration is sufficiently `slow’, KBOs can be trapped into orbital resonances that move outward w/planet.

21 How smooth is Neptune’s migration? Depends on size distribution:

22 Numerically, provided most of the mass is in <200 km bodies, OK.

23 Objects further out? Look for slow movers…

24 J S U N P

25

26

27 Orbit refined by “historical” observations:

28 a=480 AU e=0.85 i=12 q=76 AU Q=900 AU P=10,500 yr

29 Why is SEDNA’s orbit hard to understand from a solar system (only) point of view?

30

31 Numerical integration studies of individual objects from Mike B.:

32

33

34

35

36

37 ?

38 a=480 AU e=0.85 i=12 q=76 AU Q=900 AU P=10,500 yr

39

40 Where did it come from? -in situ formation -scattered by modest-sized planet @ ~70AU -close stellar encounter

41 Where did it come from? -in situ -scattered by modest-sized planet @ ~70AU -close stellar encounter

42 Where did it come from? -in situ -scattered by modest-sized planet @ ~70AU -close stellar encounter -dense stellar birth environment

43

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47 Include perturbers well beyond 30-40 AU:

48

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50 Sampling bias: To distinguish between the possible models for Sedna’s origin, you need to detect more such objects. The red arc indicates the fraction of Sedna’s orbit in which it can be detected with current technology.

51 Emerging picture: Dynamic environment, lots of movement! Radial velocity surveys are sensitive to ~Jupiter/Saturn mass planets out to >5 AU, Neptune masses further in. http://exoplanets.org/exoplanets_pub.html

52 Next time: Can we study extrasolar Kuiper belts?

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