Image: ISAS/JAXA

1. Collisional Grooming: Including Collisions in (Prohibitively Large) N-body Simulations Christopher Stark University of Maryland NASA Goddard Space Flight Center Image: ISAS/JAXA

2. Fomalhaut  Eri Kalas et al. 2005 HR 4796A Greaves et al. 1998 Schneider et al. 2009

3. Kalas et al. 2008

6. Fomalhaut  Eri Kalas et al. 2005 HR 4796A Greaves et al. 1998 Schneider et al. 2009

7. Velocity Dispersion in a Structured Debris Disk

8. Planetary gravitational forces Radiation pressure Stellar gravitational force PR + solar wind drag

9. The Collisional Grooming Algorithm Ni(t=t) = Ni(t=0)e- i Ni(t=2t) = Ni(t=t)e- i Ni = Ni(t=0) Ni(t=3t) = Ni(t=2t)e- i

10. Iterative Convergence of the Collisional Grooming Algorithm

11. Correctness of Solution to the Mass Flux Equation

12. Collision Rate in a Resonant Ring Structure

13. Collision Rate in a Resonant Ring Structure

14. No Collisions More Collisions

15. Fragmentation Ni(t=t) = Ni(t=0)e- i Ni = Ni(t=0)

16. Fragmentation

17. Fomalhaut  Eri Kalas et al. 2005 HR 4796A Greaves et al. 1998 Schneider et al. 2009

18. Distribution of KBOs

19.  = 0.6 m

20.  = 60 m

21.  = 800 m

22. Disk-Total Grain Size Distribution

23. Summary • Collisional grooming allows us to include gravitational resonant dynamics and grain-grain collisions simultaneously & self-consistently • Algorithm runs post-integration & takes ~1 hour on a single processor • Grain-grain collisions play an important role in determining debris disk morphology, even for disks with optical depths ~10-7