1 / 31

Disk Instability Models: What Works and What Does Not Work

Disk Instability Models: What Works and What Does Not Work. The Formation of Planetary Systems Heretic’s Approach to Solar System FormationFForm. Alan P. Boss Carnegie Institution of Washington. From Protostellar Disks to Planetary Systems

ciro
Download Presentation

Disk Instability Models: What Works and What Does Not Work

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Disk Instability Models: What Works and What Does Not Work The Formation of Planetary Systems Heretic’s Approach to Solar System FormationFForm Alan P. Boss Carnegie Institution of Washington From Protostellar Disks to Planetary Systems University of Western Ontario, London, Ontario, Canada May 18, 2006

  2. Outline: • Recent work on disk instability models: • Vertical convective fluxes • Survival of virtual protoplanets • Disks in binary G dwarf star systems • 200-AU-scale disks around G dwarfs • Disks around M dwarf stars • Formation of super-Earths around M dwarfs 3

  3. Disk Instability? In order for disk instability to be able to form giant protoplanets, there must be a means of cooling the disk on the time scale of the instability, which is on the order of the orbital period. Radiative cooling in an optically thick disk is too inefficient to cool the disk’s midplane, as its characteristic time scale is of order 30,000 yrs for the solar nebula at 10 AU. The only other possible mechanism for cooling the disk midplane is convective transport – can it do the job?

  4. 2 AU Temperature contours at 339 yrs Vertical scale expanded by 10 Inner edge 4 AU 20 AU ^ ^ ^ ^ ^ ^

  5. 2 AU 339 yrs Superadiabatic vertical temperature gradients (Schwarzschild criterion for convection) Vertical scale expanded by 10 4 AU 20 AU ^ ^ ^ ^ ^ ^

  6. Velocity vectors at 339 yrs 2 AU 8 AU ^ ^ ^ 14 AU

  7. Vertical Convective Energy Flux 1. For each hydrodynamical cell, calculate the vertical thermal energy flux: Fconv = - vq A E r where vq = vertical velocity, A = cell area perpendicular to the vertical velocity, E = specific internal energy of cell, and r = cell density. 2. Sum this flux over nearly horizontal surfaces to find the total vertical convective energy flux as a function of height in the disk.

  8. 339 yrs Peak flux is high enough to remove all thermal energy from this ring of gas in 50 yrs.

  9. Rapid Convective Cooling? (Boss 2004) • Radiative transfer is unable to cool disk midplanes on the dynamical time scale (a few rotational periods). • Convective transport appears to be capable of cooling disk midplanes on the dynamical time scale. • Evidence for convective transport includes Schwarzschild criterion for convection, convective cells seen in velocity vector fields, and calculations of the total vertical convective energy flux. • Assuming that the surface can radiate away the disk’s heat on a comparable time scale, marginally gravitationally unstable disks should be able to form giant protoplanets.

  10. Mayer et al. (2002) disk instability model after 800 yrs [SPH with simple thermodynamics] time evolution of clump orbits

  11. Boss (2005) Virtual protoplanet orbits for at least 1000 years, at least 30 orbits

  12. Gas Giant Planets in Multiple Star Systems • Hierarchical triple star systems (planet orbits the single member of the triple): • 16 Cygni B – about 850 AU separation • HD 178911 B – about 640 AU separation • HD 41004 A – about 23 AU separation • Binary star systems: • HD 195019 – about 150 AU separation • HD 114762 – about 130 AU separation • HD 19994 – about 100 AU separation • Gamma Cephei – about 20 AU separation • Gl 86 – about 20 AU separation • [ At least ~ 29 multiple stars have planets to date (M. Mugrauer, 2004)]

  13. Q = csW/(p G s) marginally gravitationally unstable disk Q=2 as in Nelson (2000) Q=1 highly unstable

  14. 20 AU radius disk no binary 245 years

  15. ^ to binary – at apastron 20 AU radius disk after one binary rotation period: 239 years Ms= 1 Msun Md= 0.09 Msun a = 50 AU e = 0.5

  16. Nelson (2000) used (2D) 60,000 SPH particles Thin disk so adiabatic gradient assumed in vertical direction, as if cooled by convection Surface T > 100 K means higher midplane T Artificial viscosity converts KE into heat in shock fronts and elsewhere (a = 0.002 to 0.005) Cooling time ~ 10 P Boss (2006) used over 1,000,000 grid points (3D) Fully 3D so vertical convection cools disk midplane in optically thick regions, radiation cools in optically thin regions Surface T = 50 K means lower midplane T No artificial viscosity so no irreversible heating in shock fronts and a =0 assumed Cooling time ~ 1-2 P Differences between Nelson (2000) and Boss (2006)

  17. GQ Lup b – 1 Myr-old gas giant planet at 100 AU? (Neuhauser et al. 2005)

  18. 200 AU radius disk with 0.16 Msun orbiting a 1Msun protostar after 20000 yrs (Boss 2006) => SIM!

  19. Extrasolar Planet Census: Low-mass Host Stars * Most planet-host stars are G dwarf stars like the Sun, while most nearby stars are M dwarfs, less massive than the Sun. * M4 dwarf star Gl876 (0.32 MSun) has two known gas giant planets and one sub-Neptune-mass planet. * Microlensing surveys appear to have found two Jupiter-mass planets orbiting M dwarfs. * Two M dwarfs with known planets (Gl 876, Gl 436) both have solar metallicity – neither is metal-rich. * Another M dwarf with a known planet (Gl 581) is metal-poor ([Fe/H] = -0.25) compared to the Sun. * While the frequency of giant planets around M dwarfs is uncertain, it is clearly not zero.

  20. Surface density needed for Q = 1 disk instability Initial disk surface density: Qmin = 1.5 0.5 MSun protostar 0.065 MSun disk

  21. 20 AU radius disk

  22. 20 AU radius disk

  23. 0.5 MSun protostar 0.065 MSun disk Disk surface density at 208 yr

  24. 0.5 MSun protostar 0.065 MSun disk 0.93 MJupiter clump gas density at 208 yr

  25. Clump formation by disk instability after 445 yrs in a 0.02 MSun disk orbiting a 0.1 MSun star (Boss 2006). Jupiter-mass clump at 7 AU

  26. 0.065 MSun disk with Qmin= 1.5 orbiting a 0.5 MSun protostar after 215 yrs

  27. Discovery space with latest discoveries added Discovery space with planets around M dwarf stars highlighted Gl 876 OGLE-2003-BLG-235 OGLE-2005-BLG-071 Gl 876 Gl 436 Gl 581 OGLE-2005-BLG-169 OGLE-2005-BLG-390 Gl 876

  28. Heretical Explanation for Microlensing Planets • Most stars form in regions of high-mass star formation (e.g., Orion, Carina) where their protoplanetary disks can be photoevaporated away by nearby O stars. • Photoevaporation converts gas giant protoplanets into ice giants if the protoplanet orbits outside a critical radius, which depends on the mass of the host star. • For solar-mass stars, the critical radius is > 5 AU, while for a 0.3 MSun M dwarf star, the critical radius is > 1.5 AU. • If M dwarfs have disks massive enough to undergo disk instability, then their gas giant protoplanets orbiting outside ~1.5 AU will be photoevaporated down to super-Earth mass, for M dwarfs in regions of high-mass star formation. • In low-mass star formation regions (e.g., Taurus), their gas giant protoplanets will survive to become gas giant planets.

More Related