Resolved Images of Large Cavities in Protoplanetary Transition Disks

Andrews, Sean M.; Wilner, David J.; Espaillat, Catherine; Hughes, A. Meredith; Dullemond, C. P.; McClure, Melissa; Qi, Chunhua; Brown, J. M.

doi:10.1088/0004-637x/732/1/42

Cited by 617 publications

(1,032 citation statements)

References 222 publications

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“…The process depends sensitively on the mass of the planet and accretion rate; if this is too small, this effect is not strong enough, and the small dust will flow in the gap. This is consistent with several existing observations, which show a hole at mm wavelength, but have the SED of a primordial disc (Andrews et al 2011). …”

Section: Introductionsupporting

confidence: 93%

“…If all discs go through the transition disc phase, this implies that this phase must be short-lived (of order of 10 5 years), implying that disc evolution observes a "two-time scale behaviour". Transition discs have also been imaged by sub-mm interferometers (Piétu et al 2006;Brown et al 2009;Andrews et al 2011;Isella et al 2012), confirming the presence of huge (tens of AU) cavities in the mm-dust.…”

Section: Introductionmentioning

confidence: 66%

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The long-term evolution of photoevaporating transition discs with giant planets

Rosotti

Ercolano

Owen

2015

Mon. Not. R. Astron. Soc.

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Photo-evaporation and planet formation have both been proposed as mechanisms responsible for the creation of a transition disc. We have studied their combined effect through a suite of 2d simulations of protoplanetary discs undergoing X-ray photoevaporation with an embedded giant planet. In a previous work we explored how the formation of a giant planet triggers the dispersal of the inner disc by photo-evaporation at earlier times than what would have happened otherwise. This is particularly relevant for the observed transition discs with large holes and high mass accretion rates that cannot be explained by photo-evaporation alone. In this work we significantly expand the parameter space investigated by previous simulations. In addition, the updated model includes thermal sweeping, needed for studying the complete dispersal of the disc. After the removal of the inner disc the disc is a non accreting transition disc, an object that is rarely seen in observations. We assess the relative length of this phase, to understand if it is long lived enough to be found observationally. Depending on the parameters, especially on the X-ray luminosity of the star, we find that the fraction of time spent as a non-accretor greatly varies. We build a population synthesis model to compare with observations and find that in general thermal sweeping is not effective enough to destroy the outer disc, leaving many transition discs in a relatively long lived phase with a gas free hole, at odds with observations. We discuss the implications for transition disc evolution. In particular, we highlight the current lack of explanation for the missing non-accreting transition discs with large holes, which is a serious issue in the planet hypothesis.

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Section: Introductionsupporting

confidence: 93%

Section: Introductionmentioning

confidence: 66%

The long-term evolution of photoevaporating transition discs with giant planets

Rosotti

Ercolano

Owen

2015

Mon. Not. R. Astron. Soc.

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“…Aside from the discrepancy with observed disc masses (Andrews et al 2011), this very high surface density is incompatible with the assumption of a low-disc viscosity, because it corresponds to a disc with a small Toomre Q. For the passive irradiated disc profile from Chiang & Goldreich (1997) [see their equation (14a)] with…”

Section: Constraints From Planet Formation Modelsmentioning

confidence: 99%

Slowly-growing gap-opening planets trigger weaker vortices

Hammer

Kratter

Lin

2016

Mon. Not. R. Astron. Soc.

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The presence of a giant planet in a low-viscosity disc can create a gap edge in the disc's radial density profile sharp enough to excite the Rossby wave instability. This instability may evolve into dust-trapping vortices that might explain the 'banana-shaped' features in recently observed asymmetric transition discs with inner cavities. Previous hydrodynamical simulations of planet-induced vortices have neglected the time-scale of hundreds to thousands of orbits to grow a massive planet to Jupiter size. In this work, we study the effect of a giant planet's runaway growth time-scale on the lifetime and characteristics of the resulting vortex. For two different planet masses (1 and 5 Jupiter masses) and two different disc viscosities (α = 3 × 10 −4 and 3 × 10 −5 ), we compare the vortices induced by planets with several different growth time-scales between 10 and 4000 planet orbits. In general, we find that slowly-growing planets create significantly weaker vortices with lifetimes and surface densities reduced by more than 50 per cent. For the higher disc viscosity, the longest growth time-scales in our study inhibit vortex formation altogether. Additionally, slowly-growing planets produce vortices that are up to twice as elongated, with azimuthal extents well above 180 • in some cases. These unique, elongated vortices likely create a distinct signature in the dust observations that differentiates them from the more concentrated vortices that correspond to planets with faster growth time-scales. Lastly, we find that the low viscosities necessary for vortex formation likely prevent planets from growing quickly enough to trigger the instability in self-consistent models.

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“…Evidence is growing that there is at least one mode of disk dispersal, working from the inside out. Observations of a wavelength-dependent decrease in infrared excesses (e.g., Skrutskie et al 1990;Haisch et al 2001;Espaillat et al 2012;Ribas et al 2015), or spatially resolved cavities in continuum dust emission (e.g., Andrews et al 2011;van der Marel et al 2016), indicate that dust grains in the inner disk regions are depleted before those at larger radii. Disks that show these properties have been proposed to be in a transition phase ("transitional disks") toward their dispersal (e.g., Strom et al 1989;Skrutskie et al 1990;Takeuchi & Artymowicz 2001).…”

Section: Introductionmentioning

confidence: 99%

The Depletion of Water During Dispersal of Planet-Forming Disk Regions

Banzatti

Pontoppidan

Salyk

et al. 2017

ApJ

119

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We present a new velocity-resolved survey of 2.9 μm spectra of hot H 2 O and OH gas emission from protoplanetary disks, obtained with the Cryogenic Infrared Echelle Spectrometer at the VLT (R ∼ 96,000). With the addition of archival Spitzer-IRS spectra, this is the most comprehensive spectral data set of water vapor emission from disks ever assembled. We provide line fluxes at 2.9-33 μm that probe from the dust sublimation radius at ∼0.05 au out to the region of the water snow line. With a combined data set for 55 disks, we find a new correlation between H 2 O line fluxes and the radius of CO gas emission, as measured in velocity-resolved 4.7 μm spectra (Rco), which probes molecular gaps in inner disks. We find that H 2 O emission disappears from 2.9 μm (hotter water) to 33 μm (colder water) as R co increases and expands out to the snow line radius. These results suggest that the infrared water spectrum is a tracer of inside-out water depletion within the snow line. It also helps clarify an unsolved discrepancy between water observations and models by finding that disks around stars ofgenerally have inner gaps with depleted molecular gas content. We measure radial trends in H 2 O, OH, and CO line fluxes that can be used as benchmarks for models to study the chemical composition and evolution of planet-forming disk regions at 0.05-20 au. We propose that JWST spectroscopy of molecular gas may be used as a probe of inner disk gas depletion, complementary to the larger gaps and holes detected by direct imaging and by ALMA.

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Resolved Images of Large Cavities in Protoplanetary Transition Disks

Cited by 617 publications

References 222 publications

The long-term evolution of photoevaporating transition discs with giant planets

The long-term evolution of photoevaporating transition discs with giant planets

Slowly-growing gap-opening planets trigger weaker vortices

The Depletion of Water During Dispersal of Planet-Forming Disk Regions

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