SPIRAL ARMS IN GRAVITATIONALLY UNSTABLE PROTOPLANETARY DISKS AS IMAGED IN SCATTERED LIGHT

ABSTRACT Combining 3D smoothed-particle hydrodynamics and Monte Carlo radiative transfer calculations, we examine the morphology of spiral density waves induced by gravitational instability (GI) in protoplanetary disks, as they would appear in direct images at near-infrared (NIR) wavelengths. We fin...

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Bibliographic Details
Published in:Astrophysical journal. Letters 2015-10, Vol.812 (2), p.1-7
Main Authors: Dong (董若冰), Ruobing, Hall, Cassandra, Rice, Ken, Chiang (蒋诒曾), Eugene
Format: Article
Language:English
Subjects:
Approximation
circumstellar matter
Density
Disks
Morphology
Planet formation
planets and satellites: formation
protoplanetary disks
Protoplanets
Spirals
stars: formation
stars: pre-main sequence
stars: variables: T Tauri, Herbig Ae/Be
Wavelengths
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Summary:ABSTRACT Combining 3D smoothed-particle hydrodynamics and Monte Carlo radiative transfer calculations, we examine the morphology of spiral density waves induced by gravitational instability (GI) in protoplanetary disks, as they would appear in direct images at near-infrared (NIR) wavelengths. We find that systems with disk-to-star-mass ratios q = Mdisk/M that are ∼0.25 or more may produce prominent spiral arms in NIR imaging, remarkably resembling features observed in the MWC 758 and SAO 206462 systems. The contrast of GI-induced arms at NIR wavelengths can reach a factor of ∼3, and their pitch angles are about 10°-15°. The dominant azimuthal wavenumber of GI-induced spiral arms roughly obeys m ∼ 1/q in the range 2 1/q 8. In particular, a massive disk with q 0.5 can exhibit grand-design m = 2 spirals. GI-induced arms are in approximate corotation with the local disk, and may therefore trap dust particles by pressure drag. Although GI can produce NIR spiral arms with morphologies, contrasts, and pitch angles similar to those reported in recent observations, it also makes other demands that may or may not be satisfied in any given system. A GI origin requires that the spirals be relatively compact, on scales 100 AU; that the disk be massive, q 0.25; and that the accretion rate be high, on the order of 10−6M yr−1.
ISSN:2041-8205
2041-8213
2041-8213
DOI:10.1088/2041-8205/812/2/L32