RAPID COAGULATION OF POROUS DUST AGGREGATES OUTSIDE THE SNOW LINE: A PATHWAY TO SUCCESSFUL ICY PLANETESIMAL FORMATION

Rapid orbital drift of macroscopic dust particles is one of the major obstacles to planetesimal formation in protoplanetary disks. We re-examine this problem by considering the porosity evolution of dust aggregates. We apply a porosity model based on recent N-body simulations of aggregate collisions, which allows us to study the porosity change upon collision for a wide range of impact energies. As a first step, we neglect collisional fragmentation and instead focus on dust evolution outside the snow line, where the fragmentation has been suggested to be less significant than inside the snow line because of the high sticking efficiency of icy particles. We show that dust particles can evolve into highly porous aggregates (with internal densities of much less than 0.1 g cm–3) even if collisional compression is taken into account. We also show that the high porosity triggers significant acceleration in collisional growth. This acceleration is a natural consequence of the particles' aerodynamical properties at low Knudsen numbers, i.e., at particle radii larger than the mean free path of the gas molecules. Thanks to this rapid growth, the highly porous aggregates are found to overcome the radial drift barrier at orbital radii less than 10 AU (assuming the minimum-mass solar nebula model). This suggests that, if collisional fragmentation is truly insignificant, formation of icy planetesimals is possible via direct collisional growth of submicron-sized icy particles.

[1]  S. Sirono THE SINTERING REGION OF ICY DUST AGGREGATES IN A PROTOPLANETARY NEBULA , 2011 .

[2]  Hidekazu Tanaka,et al.  PLANETARY CORE FORMATION WITH COLLISIONAL FRAGMENTATION AND ATMOSPHERE TO FORM GAS GIANT PLANETS , 2011, 1106.2047.

[3]  J. Niemela,et al.  Measuring the size of the proton , 2012 .

[4]  Alexander G. G. M. Tielens,et al.  The Physics of Dust Coagulation and the Structure of Dust Aggregates in Space , 1997 .

[5]  J. Blum,et al.  THE PHYSICS OF PROTOPLANETESIMAL DUST AGGLOMERATES. III. COMPACTION IN MULTIPLE COLLISIONS , 2009, 0902.3082.

[6]  V. Safronov,et al.  Evolution of the protoplanetary cloud and formation of the earth and the planets , 1972 .

[7]  A. Elvius From Plasma to Planet , 1972 .

[8]  S. Miyama,et al.  Magnetorotational Instability in Protoplanetary Disks. II. Ionization State and Unstable Regions , 2000, astro-ph/0005464.

[9]  H. Kimura,et al.  COLLISIONAL GROWTH CONDITIONS FOR DUST AGGREGATES , 2009 .

[10]  Koji Wada,et al.  Numerical Simulation of Dust Aggregate Collisions. II. Compression and Disruption of Three-Dimensional Aggregates in Head-on Collisions , 2008 .

[11]  K. Wada,et al.  GEOMETRIC CROSS SECTIONS OF DUST AGGREGATES AND A COMPRESSION MODEL FOR AGGREGATE COLLISIONS , 2012, 1205.1894.

[12]  T. Takeuchi,et al.  ELECTROSTATIC BARRIER AGAINST DUST GROWTH IN PROTOPLANETARY DISKS. I. CLASSIFYING THE EVOLUTION OF SIZE DISTRIBUTION , 2010, 1009.3199.

[13]  Koji Wada,et al.  THE REBOUND CONDITION OF DUST AGGREGATES REVEALED BY NUMERICAL SIMULATION OF THEIR COLLISIONS , 2011 .

[14]  K. Rice,et al.  Protostars and Planets V , 2005 .

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

[16]  N. Turner,et al.  DUST TRANSPORT IN PROTOSTELLAR DISKS THROUGH TURBULENCE AND SETTLING , 2009, 0911.1533.

[17]  J. Stone,et al.  DYNAMICS OF SOLIDS IN THE MIDPLANE OF PROTOPLANETARY DISKS: IMPLICATIONS FOR PLANETESIMAL FORMATION , 2010, 1005.4982.

[18]  J. Blum,et al.  The Physics of Protoplanetesimal Dust Agglomerates. II. Low-Velocity Collision Properties , 2007, 0711.2148.

[19]  S. Ida,et al.  Dust Growth and Settling in Protoplanetary Disks and Disk Spectral Energy Distributions. I. Laminar Disks , 2005, astro-ph/0502287.

[20]  S. Inutsuka,et al.  PROTOPLANETARY DISK WINDS VIA MAGNETOROTATIONAL INSTABILITY: FORMATION OF AN INNER HOLE AND A CRUCIAL ASSIST FOR PLANET FORMATION , 2009, 0911.0311.

[21]  B. Draine,et al.  Astrophysics of Dust , 2004 .

[22]  Koji Wada,et al.  Numerical Simulation of Density Evolution of Dust Aggregates in Protoplanetary Disks. I. Head-on Collisions , 2008 .

[23]  S. Okuzumi ELECTRIC CHARGING OF DUST AGGREGATES AND ITS EFFECT ON DUST COAGULATION IN PROTOPLANETARY DISKS , 2009, 0901.2886.

[24]  Hidekazu Tanaka,et al.  NUMERICAL MODELING OF THE COAGULATION AND POROSITY EVOLUTION OF DUST AGGREGATES , 2009, 0911.0239.

[25]  Koji Wada,et al.  Numerical Simulation of Dust Aggregate Collisions. I. Compression and Disruption of Two-Dimensional Aggregates , 2007 .

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

[27]  S. Okuzumi,et al.  MODELING MAGNETOROTATIONAL TURBULENCE IN PROTOPLANETARY DISKS WITH DEAD ZONES , 2011, 1108.4892.

[28]  T. Takeuchi,et al.  ELECTROSTATIC BARRIER AGAINST DUST GROWTH IN PROTOPLANETARY DISKS. II. MEASURING THE SIZE OF THE “FROZEN” ZONE , 2010, 1009.3101.

[29]  R. J. Geretshauser,et al.  THE PHYSICS OF PROTOPLANETESIMAL DUST AGGLOMERATES. IV. TOWARD A DYNAMICAL COLLISION MODEL , 2009, 0906.0088.