Measuring turbulence in TW Hydrae with ALMA: methods and limitations

Teague, Richard; Guilloteau, S.; Semenov, D.; Henning, Th.; Dutrey, Anne; Piétu, V.; Birnstiel, T.; Chapillon, E.; Hollenbach, D. J.; Gorti, Uma

doi:10.1051/0004-6361/201628550

Cited by 190 publications

(260 citation statements)

References 25 publications

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“…By carefully investigating for CO, CN and CS observations of the disk system TW Hya, Teague et al (2016) found an upper limit of the turbulence causing line broadening, consistent with v turb ≤ 0.2c s . Another ALMA observation of the disk HD 163296 in different CO lines by Flaherty et al (2015) supports the general finding of relatively low turbulent velocities in the disk.…”

Section: Kinematic Constraints From Line Observationsmentioning

confidence: 72%

Radiation Hydrodynamical Turbulence in Protoplanetary Disks: Numerical Models and Observational Constraints

Flock

Nelson

Turner

et al. 2017

ApJ

143

153

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Planets are born in protostellar disks, which are now observed with enough resolution to address questions about internal gas flows. Candidates for driving the flows include magnetic forces, but ionization state estimates suggest much of the gas mass decouples from magnetic fields. Thus, hydrodynamical instabilities could play a major role. We investigate disk dynamics under conditions typical for a T Tauri system, using global 3D radiation hydrodynamics simulations with embedded particles and a resolution of 70 cells per scale height. Stellar irradiation heating is included with realistic dust opacities. The disk starts in joint radiative balance and hydrostatic equilibrium. The vertical shear instability (VSI) develops into turbulence that persists up to at least 1600 inner orbits (143 outer orbits). Turbulent speeds are a few percent of the local sound speed at the midplane, increasing to 20%, or 100 m/s, in the corona. These are consistent with recent upper limits on turbulent speeds from optically thin and thick molecular line observations of TW Hya and HD 163296. The predominantly vertical motions induced by the VSI efficiently lift particles upwards. Grains 0.1 and 1 mm in size achieve scale heights greater than expected in isotropic turbulence. We conclude that while kinematic constraints from molecular line emission do not directly discriminate between magnetic and nonmagnetic disk models, the small dust scale heights measured in HL Tau and HD 163296 favor turbulent magnetic models, which reach lower ratios of the vertical kinetic energy density to the accretion stress.

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Section: Kinematic Constraints From Line Observationsmentioning

confidence: 72%

Radiation Hydrodynamical Turbulence in Protoplanetary Disks: Numerical Models and Observational Constraints

Flock

Nelson

Turner

et al. 2017

ApJ

143

153

View full text Add to dashboard Cite

show abstract

“…Within this radius the continuum emission dominates the weaker CS emission, thus continuum subtrac- tion may affect the assumed inner radii of CS. Outside of this, the emission falls off and is detected to ∼ 3.7 (Teague et al 2016), comparable to that of CO and scattered light (Andrews et al 2012;Debes et al 2013). …”

Section: Radial Featuresmentioning

confidence: 88%

“…The change in density structure and Elsasser number over this boundary forms axisymmetric zonal flows, carving the gap. A measurement of the radial extent of the dead-zone (or confirmation of its presence) would provide a great test for this instability, however previous analyses of the ionization and turbulent velocity structures have yet to detect the edge (Cleeves et al 2015b;Teague et al 2016). Furthermore, Flock et al (2015) note that no structure is seen in simulated scattered light images, contrary to the case for TW Hya.…”

Section: Disk Instabilitiesmentioning

confidence: 98%

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A Surface Density Perturbation in the TW Hydrae Disk at 95 au Traced by Molecular Emission

Teague

Semenov

Gorti

et al. 2017

ApJ

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We present ALMA Cycle 2 observations at 0.5 resolution of TW Hya of CS J = 5 − 4 emission. The radial profile of the integrated line emission displays oscillatory features outwards of 1.5 (≈ 90 au). A dip-like feature at 1.6 is coincident in location, depth and width with features observed in dust scattered light at near-infrared wavelengths. Using a thermochemical model indicative of TW Hya, gas-grain chemical modelling and non-LTE radiative transfer, we demonstrate that such a feature can be reproduced with a surface density depression, consistent with the modelling performed for scattered light observations of TW Hya. We further demonstrate that a gap in the dust distribution and dust opacity only cannot reproduce the observed CS feature. The outer enhancement at 3.1 is identified as a region of intensified desorption due to enhanced penetration of the interstellar FUV radiation at the exponential edge of the disk surface density, which intensifies the photochemical processing of gas and ices.

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“…In that case the midplane-relevant here-stays laminar. Given these uncertaintiesindeed˛T is very hard to constrain observationally (Teague et al 2016)-it is best to consider˛T as a free parameter and test how it affects the pebble accretion rates.…”

Section: The Pebble Accretion Growth Mass M P;grwmentioning

confidence: 99%

The Emerging Paradigm of Pebble Accretion

Ormel

2017

Astrophysics and Space Science Library

109

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Pebble accretion is the mechanism in which small particles ("pebbles") accrete onto big bodies (planetesimals or planetary embryos) in gas-rich environments. In pebble accretion, accretion occurs by settling and depends only on the mass of the gravitating body, not its radius. I give the conditions under which pebble accretion operates and show that the collisional cross section can become much larger than in the gas-free, ballistic, limit. In particular, pebble accretion requires the pre-existence of a massive planetesimal seed. When pebbles experience strong orbital decay by drift motions or are stirred by turbulence, the accretion efficiency is low and a great number of pebbles are needed to form Earth-mass cores. Pebble accretion is in many ways a more natural and versatile process than the classical, planetesimal-driven paradigm, opening up avenues to understand planet formation in solar and exoplanetary systems.

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Measuring turbulence in TW Hydrae with ALMA: methods and limitations

Cited by 190 publications

References 25 publications

Radiation Hydrodynamical Turbulence in Protoplanetary Disks: Numerical Models and Observational Constraints

Radiation Hydrodynamical Turbulence in Protoplanetary Disks: Numerical Models and Observational Constraints

A Surface Density Perturbation in the TW Hydrae Disk at 95 au Traced by Molecular Emission

The Emerging Paradigm of Pebble Accretion

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