Gaps, rings, and non-axisymmetric structures in protoplanetary disks

Flock, Mario; Ruge, Jan Philipp; Dzyurkevich, Natalia; Henning, Thomas; Klahr, Hubert; Wolf, S.

doi:10.1051/0004-6361/201424693

Cited by 396 publications

(433 citation statements)

References 99 publications

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“…Such a broken power law structure can be caused either by a decrease in emission inside 1 or a boost in emission outside 1 . Both these options are physically motivated: a decrease in emission could be the result of a gap which is carved out by a forming planet (Wolf & D'Angelo 2005), MHD effects (Flock et al 2015), or be the result of rapid grain growth at a condensation front (Zhang et al 2015). An extra emitting ring can be caused by fragmentation and drift-dominated dust distributions, but also by other mechanisms, such as an enhancement or pile-up in small dust grains caused by e.g.…”

Section: Discussionmentioning

confidence: 99%

Cavity and other radial substructures in the disk around HD 97048

Plas

Wright

Ménard

et al. 2016

A&A

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Context. Gaps, cavities and rings in circumstellar disks are signposts of disk evolution and planet-disk interactions. We follow the recent suggestion that Herbig Ae/Be disks with a flared disk harbour a cavity, and investigate the disk around HD 97048. Aims. We aim to resolve the 34± 4 au central cavity predicted by Maaskant et al. (2013) and to investigate the structure of the disk. Methods. We image the disk around HD 97048 using ALMA at 0.85 mm and 2.94 mm, and ATCA (multiple frequencies) observations. Our observations also include the 12 CO J=1-0, 12 CO J=3-2 and HCO + J=4-3 emission lines. Results. A central cavity in the disk around HD 97048 is resolved with a 40-46 au radius. Additional radial structure present in the surface brightness profile can be accounted for either by an opacity gap at 90 au or by an extra emitting ring at 150 au. The continuum emission tracing the dust in the disk is detected out to 355 au. The 12 CO J=3-2 disk is detected 2.4 times farther out. The 12 CO emission can be traced down to ≈ 10 au scales. Non-Keplerian kinematics are detected inside the cavity via the HCO + J=4-3 velocity map. The mm spectral index measured from ATCA observations suggests that grain growth has occurred in the HD 97048 disk. Finally, we resolve a highly inclined disk out to 150 au around the nearby 0.5 M binary ISO-ChaI 126. Conclusions. The data presented here reveal a cavity in the disk of HD 97048, and prominent radial structure in the surface brightness. The cavity size varies for different continuum frequencies and gas tracers. The gas inside the cavity follows non-Keplerian kinematics seen in HCO + emission. The variable cavity size along with the kinematical signature suggests the presence of a substellar companion or massive planet inside the cavity.

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Section: Discussionmentioning

confidence: 99%

Cavity and other radial substructures in the disk around HD 97048

Plas

Wright

Ménard

et al. 2016

A&A

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“…Therefore, if it is the case, the gas and dust have the same density distribution as the multiple-ring structure, which encourages scenarios of gas clearance by planets (Tamayo et al 2015), magnetic instabilities of the gas (Flock et al 2015), or gravitational instability (Takahashi & Inutsuka 2014). Furthermore, the rings may be Figure 3).…”

Section: Stokes Numbermentioning

confidence: 99%

Grain Size Constraints on Hl Tau With Polarization Signature

Kataoka

Muto

Momose

et al. 2016

ApJ

113

147

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The millimeter-wave polarization of the protoplanetary disk around HL Tau has been interpreted as the emission from elongated dust grains aligned with the magnetic field in the disk. However, the self-scattering of thermal dust emission may also explain the observed millimeter-wave polarization. In this paper, we report a modeling of the millimeter-wave polarization of the HL Tau disk with the self-polarization. Dust grains are assumed to be spherical and to have a power-law size distribution. We change the maximum grain size with a fixed dust composition in a fixed disk model to find the grain size to reproduce the observed signature. We find that the direction of the polarization vectors and the polarization degree can be explained with the self-scattering. Moreover, the polarization degree can be explained only if the maximum grain size is ∼150 μm. The obtained grain size from the polarization is different from that which has been previously expected from the spectral index of the dust opacity coefficient (a millimeter or larger) if the emission is optically thin. We discuss that porous dust aggregates may solve the inconsistency of the maximum grain size between the two constraints.

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“…Different processes that are not mutually exclusive, can rule the disk evolution and create the observed structures, such as photoevaporation or magneto-rotational instabilities (e.g. Alexander et al 2014;Flock et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Variability and dust filtration in the transition disk J160421.7-213028 observed in optical scattered light

Pinilla

Boer

Benisty

et al. 2015

A&A

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Context. Protoplanetary disks around young stars are the birth-sites of planets. Spectral energy distributions and direct images of a subset of disks known as transition disks reveal dust-depleted inner cavities. Some of these disks show asymmetric structures in thermal submillimetre emission and optical scattered light. These structures can be the result of planet(s) or companions embedded in the disk. Aims. We aim to detect and analyse the scattered light of the transition disk J160421.7-213028, identify disk structures, and compare the results with previous observations of this disk at other wavelengths. Methods. We obtained and analysed new polarised intensity observations of the transition disk J160421.7-213028 with VLT/SPHERE using the visible light instrument ZIMPOL at R -band (0.626 µm). We probed the disk gap down to a radius of confidence of 0.1 (∼15 AU at 145 pc). We interpret the results in the context of dust evolution when planets interact with the parental disk. Results. We observe a gap from 0.1 to 0.3 (∼15 to 40 AU) and a bright annulus as previously detected by HiCIAO H-band observations at 1.65µm. The radial width of the annulus is around 40 AU, and its centre is at ∼61 AU from the central star. The peak of the reflected light at 0.626 µm is located 20 AU inward of the cavity detected in the submillimetre. In addition, we detect a dip at a position angle of ∼46.2 ± 5.4 • . A dip was also detected with HiCIAO, but located at ∼85 • . If the dip observed with HiCIAO is the same, this suggests an average dip rotation of ∼12 • /year, which is inconsistent with the local Keplerian angular velocity of ∼0.8 • /yr at ∼61 AU. Conclusions. The spatial discrepancy in the radial emission in J160421.7-213028 at different wavelengths is consistent with dust filtration at the outer edge of a gap carved by a massive planet. The dip rotation can be interpreted as fast variability of the inner disk and/or the presence of a warp or circumplanetary material of a planet at ∼9.6 AU.

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Gaps, rings, and non-axisymmetric structures in protoplanetary disks

Cited by 396 publications

References 99 publications

Cavity and other radial substructures in the disk around HD 97048

Cavity and other radial substructures in the disk around HD 97048

Grain Size Constraints on Hl Tau With Polarization Signature

Variability and dust filtration in the transition disk J160421.7-213028 observed in optical scattered light

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