THE SPIRAL WAVE INSTABILITY INDUCED BY A GIANT PLANET. I. PARTICLE STIRRING IN THE INNER REGIONS OF PROTOPLANETARY DISKS

ABSTRACT We have recently shown that spiral density waves propagating in accretion disks can undergo a parametric instability by resonantly coupling with and transferring energy into pairs of inertial waves (or inertial-gravity waves when buoyancy is important). In this paper, we perform inviscid th...

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Bibliographic Details
Published in:The Astrophysical journal 2016-12, Vol.833 (2), p.126
Main Authors: Bae, Jaehan, Nelson, Richard P., Hartmann, Lee
Format: Article
Language:English
Subjects:
ACCRETION DISKS
Asteroids
Astrophysics
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
Chemical speciation
Chondrule
Computational fluid dynamics
Computer simulation
COMPUTERIZED SIMULATION
DENSITY
DIFFUSION
Diffusion rate
Extrasolar planets
Gas giant planets
Gravitational waves
GRAVITY WAVES
HYDRODYNAMICS
instabilities
Instability
Jupiter
MASS
ORBITS
Organic chemistry
PARAMETRIC INSTABILITIES
Planet formation
planet-disk interactions
Planetary orbits
Planets
planets and satellites: formation
Protoplanetary disks
PROTOPLANETS
SATELLITES
SCALE HEIGHT
SOLIDS
Stability
Stirring
THREE-DIMENSIONAL CALCULATIONS
TURBULENCE
Vertical diffusion
Wave propagation
waves
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Summary:ABSTRACT We have recently shown that spiral density waves propagating in accretion disks can undergo a parametric instability by resonantly coupling with and transferring energy into pairs of inertial waves (or inertial-gravity waves when buoyancy is important). In this paper, we perform inviscid three-dimensional global hydrodynamic simulations to examine the growth and consequence of this instability operating on the spiral waves driven by a Jupiter-mass planet in a protoplanetary disk. We find that the spiral waves are destabilized via the spiral wave instability (SWI), generating hydrodynamic turbulence and sustained radially alternating vertical flows that appear to be associated with long wavelength inertial modes. In the interval , where Rp denotes the semimajor axis of the planetary orbit (assumed to be 5 au), the estimated vertical diffusion rate associated with the turbulence is characterized by . For the disk model considered here, the diffusion rate is such that particles with sizes up to several centimeters are vertically mixed within the first pressure scale height. This suggests that the instability of spiral waves launched by a giant planet can significantly disperse solid particles and trace chemical species from the midplane. In planet formation models where the continuous local production of chondrules/pebbles occurs over Myr timescales to provide a feedstock for pebble accretion onto these bodies, this stirring of solid particles may add a time constraint: planetary embryos and large asteroids have to form before a gas giant forms in the outer disk, otherwise the SWI will significantly decrease the chondrule/pebble accretion efficiency.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/833/2/126