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Planetesimals in Turbulent Disks

This study investigates how planetesimals behave in realistic turbulent disks. It explores the effects of migration, orbital eccentricity and inclination, velocity dispersion, and dead zones. Numerical techniques and simulations using test particles are used to quantify these behaviors. The study also examines the motion of individual particles, including eccentricity change and inclination growth. The results suggest that turbulent disks can lead to the formation and diffusion of planetesimals, potentially preserving a significant fraction against gas-driven migration.

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Planetesimals in Turbulent Disks

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  1. Planetesimals in Turbulent Disks Mordecai-Mark Mac Low Chao-Chin Yang American Museum of Natural History Jeffrey S. Oishi University of California at Berkeley Kristen Menou Columbia University

  2. Planetesimals form within gas disks • Laminar disks cause migration • Real disks are MRI turbulent, though • How do planetesimals behave in more realistic disks? • migration • orbital ellipticity & inclination • velocity dispersion • dead zones

  3. Numerical Techniques • Pencil Code (Brandenburg & Dobler 2002) http://www.nordita.dk/data/brandenb/pencil-code/ • Finite-difference MHD code (w / particles) • Sixth-order spatial, third-order time • Hyperdiffusion for time-centered scheme • Div B = 0 maintained using vector potential • Parallelized along pencils using MPI • Height-dependent Ohmic resistivity • Shearing-sheet local box w/stratification

  4. Turbulent Migration Nelson & Papaloizou 04 A random walk! see also: Papaloizou & Nelson 03 Laughlin et al 04 Nelson 05 Torque t

  5. How do torques act over multiple orbits? • Use test particles to follow orbital evolution. • Following large numbers allows quantification of random walks. • initial conditions: • net flux to maintain constant alpha • zero ellipticity, finite ellipticity orbits • low and high mass disks (constant Q) • unstratified and stratified ideal MHD

  6. Motion of an Individual Particle Yang, Mac Low, & Menou, 2009, in prep • Mean radial distance → radial drift • Amplitude of epicycles → eccentricity e • Amplitude of vertical oscillations → inclination i

  7. Eccentricity Change extends semi-analytic result of Ogihara, Ida & Morbidelli 07, based on Laughlin Steinacker & Adams 04 to both excitation and damping Yang, Mac Low & Menou 2009, in prep

  8. Inclination Growth Yang, Mac Low & Menou 2009, in prep Over a lifetime of 1 Myr, at R~ 30 AU, i < 0.2 degrees

  9. quantifies random walk of Nelson & Papaloizou 05 Radial Drift Yang, Mac Low & Menou 2009, in prep

  10. cosmic ray ionization (Gammie 96) dust absorbs charge (Wardle & Ng 99, Sano et al. 00 ) trace metal ions (Fromang et al 02) turbulent mixing of ions (Inutsuka & Sano 05, Ilgner & Nelson 06ab, 08, Turner et al. 07) Dead Zones thicker thinner

  11. Magnetic pressure vs time ReM=3 ReM=30 Oishi, Mac Low, & Menou 07 ReM=100 ReM=∞

  12. Shakura & Sunyaev viscous stress Dead zones don’t cut off accretion (confirms & extends Fleming & Stone 2003) Oishi, Mac Low, & Menou 07

  13. Advection-Diffusion Approx • Johnson, Goodman, & Menou (2006) • Type I migration = advection • Turbulent random walk = diffusion • Treat using Fokker-Planck model • Assumes stationary torques, finite correlation times. • -> diffusion shortens lifetimes on average, but allows a few to survive to very long times

  14. Stationary torque distributions Finite correlation times. Oishi, Mac Low, & Menou 07

  15. Torques decrease, but do not vanish in dead zones Oishi, Mac Low, & Menou (2007)

  16. Turbulence Parameter MRI diffusion coefficient Johnson et al. 06 Nelson 05 found  = 0.5 in global, unstratified, ideal MRI models dead zone thickness Oishi, Mac Low, & Menou 07

  17. Mp = 10-2 M 0.1 diffusive 1 10  = 0.2 advective MMSN planetesimals can be in diffusive regime… Johnson, Goodman & Menou 06 Oishi, Mac Low & Menou 07

  18. Conclusions • MRI turbulence excites only modest growth in eccentricity and inclination. • Our shearing-sheet results suggest low radial velocity dispersions, allowing planetesimal formation by collision. • MRI turbulence will cause populations of small planetesimals to diffuse both inwards and outwards, potentially leading to preservation of a significant fraction against gas-driven migration.

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