The Resonant Captures of TNOs

1. The Resonant Captures of TNOs Ing-Guey Jiang (NCU, Taiwan) Li-Chin Yeh (NHCUE, Taiwan)

2. Outline • The Resonances • The Resonant TNOs 3. Review of Previous Work 4. The Model 5. The Results 6. Conclusions

3. The Resonances • GJ 876 and HD 82943 are in 2:1 Resonance • 47 UMa is close to 7:3 Resonance • 55 Cancri are confirmed to be in 3:1 Resonance • Kirkwood Gaps in Asteroid Belt • What mechanism make them in resonance ? • Are these systems dynamically stable ?

4. The Resonant Trans Neptunian Objects • Also called “Plutinoes” • They are in 3:2 mean motion resonance with the Neptune • They are about 1/3 of whole TNO population • There are only seveal TNOs in 2:1 resonance

5. Malhotra (1995) • Possible migrations suggested by Fernandez & Ip (1984) • Assuming pure radial migration • The Neptune was migrating outward • Its mean motion resonance is swept ahead through the Kuiper Belt and captures Pluto along with plutinoes into 3:2 resonance • This theory predicted the populations of the 3:2 and 2:1 resonances to be the same order • Zhou et al. (2002)’s stochastic migration

6. The Migrating Orbit • Pure radial migration is too naïve • Eccentricity should increase (Yeh and Jiang 2001) • Neptune is currently on a circular orbit • Thommes et al. (1999) showed that one needs a massive Kuiper Belt to circularize the Neptune’s orbit

7. The Mass of Kuiper Belt • There is an observational upper limit, about 0.1 Earth mass • If it was more massive, it has to be depleted • Levison and Morbidelli (2003) proposed a pushing-out model but only have 2:1 TNOs • Could Neptune form around current positions ? Bryden et al. (2000) claimed “Yes”

8. The Drag-Induced Resonant Capture • The TNOs shall be forming while the proto-stellar disc is there • It influences the proto-TNOs • TNOs are losing energy due to Drag • Drag might make the TNOs migrate inward • Could these TNOs get captured into resonance by the Neptune ? • Into 3:2 or 2:1 ?

9. Jiang & Yeh (2004) • A system of the Sun-Neptune-Disc and test particles • The disc mass is 0.01 Solar Mass, giving both gravitational force and drag • 900 test particles are randomly placed in the region around 30 to 60 AU from the Sun • The simulation lasts about 10^7 years • Calculating both 3:2 and 2:1 Resonant Arguments • Neptune already on circular orbit, no matter where it was formed

10. The Results • Particles migrate inward due to drag • Number of particles captured into 3:2 resonance steadily increases with time • Great fraction of particles are captured into 3:2 resonance by the end of simulation • None is captured into 2:1 resonance • However, only one drag strength is studied • The nature of test particles is not assigned

13. The Recent Work • Try different drag strength • Test particles represent km-sized planetesimals • Still more captured into 3:2 but the ratio of particles captured into 3:2 over the ones in 2:1 depends on the drag strength, i.e. migrating speed • We will consider the capture of dust grains

14. Conclusions • Disc’ drag reduces particles’ energy and make them migrate inward • We can produce 3:2 resonant TNOs easily and thus seem to be an attractive mechanism • The main problem: Was drag strong enough ? • Youdin & Chiang (2004) shows that a model with MNSN will have enough drag to make grains migrate inward • The main concern of Neptune’s outward migration: it cannot be a purely radial migration, it could be complicated • Combinations with 2 possibilities is an interesting work