Giant Planet Migration, Disk Evolution, and the Origin of Transitional Disks

We present models of giant planet migration in evolving protoplanetary disks. Our disks evolve subject to viscous transport of angular momentum and photoevaporation, while planets undergo Type II migration. We use a Monte Carlo approach, running large numbers of models with a range in initial condit...

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Veröffentlicht in:	The Astrophysical journal 2009-10, Vol.704 (2), p.989-1001
Hauptverfasser:	Alexander, Richard D, Armitage, Philip J
Format:	Artikel
Sprache:	eng
Schlagworte:	ACCRETION DISKS ANGULAR MOMENTUM Astronomy ASTROPHYSICS, COSMOLOGY AND ASTRONOMY CALCULATION METHODS DISTRIBUTION Earth, ocean, space Exact sciences and technology JUPITER PLANET MASS MONTE CARLO METHOD ORBITS PLANETS PROTOPLANETS SPATIAL DISTRIBUTION
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container_title	The Astrophysical journal
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creator	Alexander, Richard D Armitage, Philip J
description	We present models of giant planet migration in evolving protoplanetary disks. Our disks evolve subject to viscous transport of angular momentum and photoevaporation, while planets undergo Type II migration. We use a Monte Carlo approach, running large numbers of models with a range in initial conditions. We find that relatively simple models can reproduce both the observed radial distribution of extrasolar giant planets, and the lifetimes and accretion histories of protoplanetary disks. The use of state-of-the-art photoevaporation models results in a degree of coupling between planet formation and disk clearing, which has not been found previously. Some accretion across planetary orbits is necessary if planets are to survive at radii 1.5 AU, and if planets of Jupiter mass or greater are to survive in our models they must be able to form at late times, when the disk surface density in the formation region is low. Our model forms two different types of 'transitional' disks, embedded planets and clearing disks, which show markedly different properties. We find that the observable properties of these systems are broadly consistent with current observations, and highlight useful observational diagnostics. We predict that young transition disks are more likely to contain embedded giant planets, while older transition disks are more likely to be undergoing disk clearing.
doi_str_mv	10.1088/0004-637X/704/2/989
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Our disks evolve subject to viscous transport of angular momentum and photoevaporation, while planets undergo Type II migration. We use a Monte Carlo approach, running large numbers of models with a range in initial conditions. We find that relatively simple models can reproduce both the observed radial distribution of extrasolar giant planets, and the lifetimes and accretion histories of protoplanetary disks. The use of state-of-the-art photoevaporation models results in a degree of coupling between planet formation and disk clearing, which has not been found previously. Some accretion across planetary orbits is necessary if planets are to survive at radii 1.5 AU, and if planets of Jupiter mass or greater are to survive in our models they must be able to form at late times, when the disk surface density in the formation region is low. Our model forms two different types of 'transitional' disks, embedded planets and clearing disks, which show markedly different properties. 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subjects	ACCRETION DISKS ANGULAR MOMENTUM Astronomy ASTROPHYSICS, COSMOLOGY AND ASTRONOMY CALCULATION METHODS DISTRIBUTION Earth, ocean, space Exact sciences and technology JUPITER PLANET MASS MONTE CARLO METHOD ORBITS PLANETS PROTOPLANETS SPATIAL DISTRIBUTION
title	Giant Planet Migration, Disk Evolution, and the Origin of Transitional Disks
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