Planet formation bursts at the borders of the dead zone in 2D numerical simulations of circumstellar disks

Context. As accretion in protoplanetary disks is enabled by turbulent viscosity, the border between active and inactive (dead) zones constitutes a location where there is an abrupt change in the accretion flow. The gas accumulation that ensues triggers the Rossby wave instability, which in turn saturates into anticyclonic vortices. It has been suggested that the trapping of solids within them leads to a burst of planet formation on very short timescales. Aims. We study in the formation and evolution of the vortices in greater detail, focusing on the implications for the dynamics of embedded solid particles and planet formation. Methods. We performed two-dimensional global simulations of the dynamics of gas and solids in a non-magnetized thin protoplanetary disk with the Pencil code. We used multiple particle species of radius 1, 10, 30, and 100 cm. We computed the particles' gravitational interaction by a particle-mesh method, translating the particles' number density into surface density and computing the corresponding self-gravitational potential via fast Fourier transforms. The dead zone is modeled as a region of low viscosity. Adiabatic and locally isothermal equations of state are used. Results. The Rossby wave instability is triggered under a variety of conditions, thus making vortex formation a robust process. Inside the vortices, fast accumulation of solids occurs and the particles collapse into objects of planetary mass on timescales as short as five orbits. Because the drag force is size-dependent, aerodynamical sorting ensues within the vortical motion, and the first bound structures formed are composed primarily of similarly-sized particles. In addition to erosion due to ram pressure, we identify gas tides from the massive vortices as a disrupting agent of formed protoplanetary embryos. We find evidence that the backreaction of the drag force from the particles onto the gas modifies the evolution of the Rossby wave instability, with vortices being launched only at later times if this term is excluded from the momentum equation. Even though the gas is not initially gravitationally unstable, the vortices can grow to Q ≈ 1 in locally isothermal runs, which halts the inverse cascade of energy towards smaller wavenumbers. As a result, vortices in models without self-gravity tend to rapidly merge towards a $m = 2$ or $m =1 $ mode, while models with self-gravity retain dominant higher order modes ($m = 4$ or $m = 3$) for longer times. Non-selfgravitating disks thus show fewer and stronger vortices. We also estimate the collisional velocity history of the particles that compose the most massive embryo by the end of the simulation, finding that the vast majority of them never experienced a collision with another particle at speeds faster than 1 m s -1 . This result lends further support to previous studies showing that vortices provide a favorable environment for planet formation.

[1]  Simulations of dust-trapping vortices in protoplanetary discs , 2003, astro-ph/0310059.

[2]  Alan P. Boss,et al.  On Pressure Gradients and Rapid Migration of Solids in a Nonuniform Solar Nebula , 2003 .

[3]  C. Terquem New Composite Models of Partially Ionized Protoplanetary Disks , 2008, 0808.3897.

[4]  T. Henning,et al.  Coagulation, fragmentation and radial motion of solid particles in protoplanetary disks , 2007, 0711.2192.

[5]  Hui Li,et al.  Rossby Wave Instability of Thin Accretion Disks. II. Detailed Linear Theory , 1999, astro-ph/9907279.

[6]  T. Henning,et al.  Survival of the mm-cm size grain population observed in protoplanetary disks , 2007, 0704.2332.

[7]  A link between the semimajor axis of extrasolar gas giant planets and stellar metallicity , 2005, astro-ph/0501313.

[8]  A. Johansen,et al.  Embryos grown in the dead zone. Assembling the first protoplanetary cores in low mass self-gravitati , 2008, 0807.2622.

[9]  J. Stone,et al.  Kinematics of solid particles in a turbulent protoplanetary disc , 2008, 0801.3646.

[10]  A. Johansen,et al.  Standing on the shoulders of giants : Trojan Earths and vortex trapping in low mass self-gravitating protoplanetary disks of gas and solids , 2008, 0810.3192.

[11]  P. Marcus Vortex dynamics in a shearing zonal flow , 1990, Journal of Fluid Mechanics.

[12]  Local Magnetohydrodynamic Models of Layered Accretion Disks , 2002, astro-ph/0210541.

[13]  沢本 正樹,et al.  面内振動する粗面近くでの流速測定(Journal of Fluid Mechanics,Vol.73,Part 4,1976 2) , 1976 .

[14]  S. Weidenschilling,et al.  Dust to planetesimals: Settling and coagulation in the solar nebula , 1980 .

[15]  S. Sirono Conditions for collisional growth of a grain aggregate , 2004 .

[16]  MPIA Heidelberg,et al.  Protoplanetary Disk Turbulence Driven by the Streaming Instability: Linear Evolution and Numerical Methods , 2007, astro-ph/0702625.

[17]  Turbulence in Accretion Disks: Vorticity Generation and Angular Momentum Transport via the Global Baroclinic Instability , 2002, astro-ph/0211629.

[18]  B. Dubrulle,et al.  The Dust Subdisk in the Protoplanetary Nebula , 1995 .

[19]  M. Sekiya Quasi-Equilibrium Density Distributions of Small Dust Aggregations in the Solar Nebula , 1998 .

[20]  S. A. Colgate,et al.  Rossby Wave Instability of Thin Accretion Disks. III. Nonlinear Simulations , 2000, astro-ph/0012479.

[21]  A. Tielens,et al.  Dust coagulation in protoplanetary disks: porosity matters , 2006, astro-ph/0610030.

[22]  Hubert Klahr,et al.  A coagulation-fragmentation model for the turbulent growth and destruction of preplanetesimals , 2008, 0802.3331.

[23]  L. Hartmann,et al.  Masses and mass distributions of protoplanetary disks , 2008 .

[24]  R. Lyttleton On the formation of planets from a solar nebula , 1972 .

[25]  A. Johansen,et al.  Global magnetohydrodynamical models of turbulence in protoplanetary disks. I. A cylindrical potentia , 2007, 0705.4090.

[26]  Miguel de Val-Borro,et al.  Vortex generation in protoplanetary disks with an embedded giant planet , 2007, 0706.3200.

[27]  N. Turner,et al.  Dead Zone Accretion Flows in Protostellar Disks , 2008, 0804.2916.

[28]  S. Weidenschilling,et al.  Aerodynamics of solid bodies in the solar nebula. , 1977 .

[29]  Jonathan P. Williams,et al.  Circumstellar Dust Disks in Taurus-Auriga: The Submillimeter Perspective , 2005, astro-ph/0506187.

[30]  G. Wurm,et al.  Eolian Erosion of Dusty Bodies in Protoplanetary Disks , 2006 .

[31]  K. Keil,et al.  Protostars and Planets V , 2007 .

[32]  C. Gammie,et al.  Vortices in Thin, Compressible, Unmagnetized Disks , 2005, astro-ph/0604034.

[33]  Accelerated planetesimal growth in self-gravitating protoplanetary discs , 2004, astro-ph/0408390.

[34]  J. M. Stone,et al.  The Formation and Structure of a Strongly Magnetized Corona above a Weakly Magnetized Accretion Disk , 1999, astro-ph/9912135.

[35]  A. Ferrari,et al.  Aspect Ratio Dependence in Magnetorotational Instability Shearing Box Simulations , 2008, 0805.1172.

[36]  Jeffrey S. Oishi,et al.  Turbulent Torques on Protoplanets in a Dead Zone , 2007, astro-ph/0702549.

[37]  E. A. Spiegel,et al.  Particle aggregation in a turbulent Keplerian flow , 1998, astro-ph/9810336.

[38]  T. Henning,et al.  Dust Sedimentation and Self-sustained Kelvin-Helmholtz Turbulence in Protoplanetary Disk Midplanes , 2005, astro-ph/0512272.

[39]  M. Tagger,et al.  Reviving Dead Zones in accretion disks by Rossby vortices at their boundaries , 2005 .

[40]  Arrow,et al.  The Physics of Fluids , 1958, Nature.

[41]  A. Boss Evolution of the Solar Nebula. V. Disk Instabilities with Varied Thermodynamics , 2002 .

[42]  J. Lunine,et al.  Protostars and planets III , 1993 .

[43]  A. Johansen,et al.  Protoplanetary Disk Turbulence Driven by the Streaming Instability: Non-Linear Saturation and Particle Concentration , 2007, astro-ph/0702626.

[44]  J. Cuzzi,et al.  Closed-form expressions for particle relative velocities induced by turbulence , 2007, astro-ph/0702303.

[45]  Ricardo Hueso,et al.  Evolution of protoplanetary disks: Constraints from DM Tauri and GM Aurigae , 2005 .

[46]  A. Provenzale,et al.  Forming Planetesimals in Vortices , 1996 .

[47]  Pascale Garaud,et al.  On the Evolution and Stability of a Protoplanetary Disk Dust Layer , 2004 .

[48]  Hui Li,et al.  Rossby Wave Instability of Keplerian Accretion Disks , 1998, astro-ph/9809321.

[49]  S. Weidenschilling The distribution of mass in the planetary system and solar nebula , 1977 .

[50]  Three-dimensional Vortices in Stratified Protoplanetary Disks , 2005, astro-ph/0501267.

[51]  APJ IN PRESS Preprint typeset using LATEX style emulateapj v. 05/04/06 THREE DIMENSIONAL COMPRESSIBLE HYDRODYNAMIC SIMULATIONS OF VORTICES IN DISKS , 2006 .

[52]  S. Crow Stability theory for a pair of trailing vortices , 1970 .

[53]  T. Nakano,et al.  EFFECTS OF RADIONUCLIDES ON THE IONIZATION STATE OF PROTOPLANETARY DISKS AND DENSE CLOUD CORES , 2008 .

[54]  J. E. Pringle,et al.  Episodic accretion in magnetically layered protoplanetary discs , 2001 .

[55]  CRITICAL PROTOPLANETARY CORE MASSES IN PROTOPLANETARY DISKS AND THE FORMATION OF SHORT-PERIOD GIANT PLANETS , 1999, astro-ph/9903310.

[56]  Formation of Giant Planets by Concurrent Accretion of Solids and Gas inside an Anticyclonic Vortex , 2005, astro-ph/0510479.

[57]  W. Rice,et al.  Vortices in self‐gravitating gaseous discs , 2009, 0901.1617.

[58]  C. Helling,et al.  Dust in brown dwarfs. II. The coupled problem of dust formation and sedimentation , 2003 .

[59]  A. Quillen,et al.  The vertical structure of planet-induced gaps in protoplanetary discs , 2007, 0709.1649.

[60]  A. Youdin,et al.  Planetesimal Formation by Gravitational Instability , 2002, astro-ph/0207536.

[61]  A. Youdin From Grains to Planetesimals , 2008, 0807.1114.

[62]  Karim Shariff,et al.  Toward Planetesimals: Dense Chondrule Clumps in the Protoplanetary Nebula , 2008, 0804.3526.

[63]  C. Dullemond,et al.  A representative particle approach to coagulation and fragmentation of dust aggregates and fluid droplets , 2008, 0807.5052.

[64]  J. Hawley,et al.  A powerful local shear instability in weakly magnetized disks. I - Linear analysis. II - Nonlinear evolution , 1990 .

[65]  M. de Val-Borro,et al.  A comparative study of disc–planet interaction , 2006 .

[66]  M. Petersen,et al.  Baroclinic Vorticity Production in Protoplanetary Disks. I. Vortex Formation , 2006, astro-ph/0611528.

[67]  Planetesimal formation via fragmentation in self-gravitating protoplanetary discs , 2006, astro-ph/0607268.

[68]  Charles F. Gammie,et al.  Layered Accretion in T Tauri Disks , 1996 .

[69]  Giuseppe Lodato,et al.  Classical disc physics , 2008 .

[70]  T. Henning,et al.  Planetesimal formation near the snow line in MRI-driven turbulent protoplanetary disks , 2008, 0806.1646.

[71]  The Global Baroclinic Instability in Accretion Disks. II. Local Linear Analysis , 2004, astro-ph/0401449.

[72]  Jeffrey S. Oishi,et al.  Rapid planetesimal formation in turbulent circumstellar disks , 2007, Nature.

[73]  P. Goldreich,et al.  The formation of planetesimals. , 1973 .

[74]  Andrew N. Youdin,et al.  Streaming Instabilities in Protoplanetary Disks , 2004, astro-ph/0409263.