2,013 research outputs found
Empirical Temperature Measurement in Protoplanetary Disks
Accurate measurement of temperature in protoplanetary disks is critical to
understanding many key features of disk evolution and planet formation, from
disk chemistry and dynamics, to planetesimal formation. This paper explores the
techniques available to determine temperatures from observations of single,
optically thick molecular emission lines. Specific attention is given to issues
such as inclusion of optically thin emission, problems resulting from continuum
subtraction, and complications of real observations. Effort is also made to
detail the exact nature and morphology of the region emitting a given line. To
properly study and quantify these effects, this paper considers a range of disk
models, from simple pedagogical models, to very detailed models including full
radiative transfer. Finally, we show how use of the wrong methods can lead to
potentially severe misinterpretations of data, leading to incorrect
measurements of disk temperature profiles. We show that the best way to
estimate the temperature of emitting gas is to analyze the line peak emission
map without subtracting continuum emission. Continuum subtraction, which is
commonly applied to observations of line emission, systematically leads to
underestimation of the gas temperature. We further show that once observational
effects such as beam dilution and noise are accounted for, the line brightness
temperature derived from the peak emission is reliably within 10-15% of the
physical temperature of the emitting region, assuming optically thick emission.
The methodology described in this paper will be applied in future works to
constrain the temperature, and related physical quantities, in protoplanetary
disks observed with ALMA.Comment: 24 pages, 16 figures, ApJ in pres
New constraints on dust grain size and distribution in CQ Tau
Grain growth in circumstellar disks is expected to be the first step towards
the formation of planetary systems. There is now evidence for grain growth in
several disks around young stars. Radially resolved images of grain growth in
circumstellar disks are believed to be a powerful tool to constrain the dust
evolution models and the initial stage for the formation of planets. In this
paper we attempt to provide these constraints for the disk surrounding the
young star CQ Tau. This system was already suggested from previous studies to
host a population of grains grown to large sizes. We present new high angular
resolution (0.3-0.9 arcsec) observations at wavelengths from 850um to 3.6cm
obtained at the SMA, IRAM-PdBI and NRAO-VLA interferometers. We perform a
combined analysis of the spectral energy distribution and of the
high-resolution images at different wavelengths using a model to describe the
dust thermal emission from the circumstellar disk. We include a prescription
for the gas emission from the inner regions of the system. We detect the
presence of evolved dust by constraining the disk averaged dust opacity
coefficient beta (computed between 1.3 and 7mm) to be 0.6+/-0.1. This confirms
the earlier suggestions that the disk contains dust grains grown to significant
sizes and puts this on firmer grounds by tightly constraining the gas
contamination to the observed fluxes at mm-cm wavelengths. We report some
evidence of radial variations in dust properties, but current resolution and
sensitivity are still too low for definitive results.Comment: 9 pages, A&A in pres
On the Radio Detectability of Circumplanetary Discs
Discs around young planets, so-called circumplanetary discs (CPDs), are essential for planet growth, satellite formation, and planet detection. We study the millimetre and centimetre emission from accreting CPDs by using the simple α disc model. We find that it is easier to detect CPDs at shorter radio wavelengths (e.g. λ ≲ 1 mm). For example, if the system is 140 pc away from us, deep observations (e.g. 5 h) at ALMA Band 7 (0.87 mm) are sensitive to as small as 0.03 lunar mass of dust in CPDs. If the CPD is around a Jupiter mass planet 20 au away from the host star and has a viscosity parameter α ≲ 0.001, ALMA can detect this disc when it accretes faster than 10−10M⊙yr−110−10M⊙yr−1 . ALMA can also detect the \u27minimum mass sub-nebulae\u27 disc if such a disc exists around a young planet in young stellar objects. However, to distinguish the embedded compact CPD from the circumstellar disc material, we should observe circumstellar discs with large gaps/cavities using the highest resolution possible. We also calculate the CPD fluxes at VLA bands, and discuss the possibility of detecting radio emission from jets/winds launched in CPDs. Finally we argue that, if the radial drift of dust particles is considered, the drifting time-scale for millimetre dust in CPDs can be extremely short. It only takes 102–103 yr for CPDs to lose millimetre dust. Thus, for CPDs to be detectable at radio wavelengths, mm-sized dust in CPDs needs to be replenished continuously, or the disc has a significant fraction of micron-sized dust or a high gas surface density so that the particle drifting time-scale is long, or the radial drift is prevented by other means (e.g. pressure traps)
An ALMA Continuum Survey of Circumstellar Disks in the Upper Scorpius OB Association
We present ALMA 880 micron continuum observations of 20 K and M-type stars in
the Upper Scorpius OB association that are surrounded by protoplanetary disks.
These data are used to measure the dust content in disks around low mass stars
(0.1-1.6 Msun) at a stellar age of 5-11 Myr. Thirteen sources were detected in
the 880 micron dust continuum at >3 sigma with inferred dust masses between 0.3
and 52 Mearth. The dust masses tend to be higher around the more massive stars,
but the significance is marginal in that the probability of no correlation is p
~ 0.03. The evolution in the dust content in disks was assessed by comparing
the Upper Sco observations with published continuum measurements of disks
around ~ 1-2 Myr stars in the Class II stage in the Taurus molecular cloud.
While the dust masses in the Upper Sco disks are on average lower than in
Taurus, any difference in the dust mass distributions is significant at less
than 3sigma. For stellar masses between 0.49 Msun and 1.6 Msun, the mean dust
mass in disks is lower in Upper Sco relative to Taurus by Delta log Mdust =
0.44 +/-0.26.Comment: Accepted by Ap
On the nature of the transition disk around LkCa 15
We present CARMA 1.3 mm continuum observations of the T Tauri star LkCa
15,which resolve the circumstellar dust continuum emission on angular scales
between 0.2-3 arcsec, corresponding to 28-420 AU at the distance of the star.
The observations resolve the inner gap in the dust emission and reveal an
asymmetric dust distribution in the outer disk. (Abridge) We calculate that 90%
of the dust emission arises from an azimuthally symmetric ring that contains
about 5x10^{-4} M_sun of dust. A low surface-brightness tail that extends to
the northwest out to a radius of about 300 AU contains the remaining 10% of the
observed continuum emission. The ring is modeled with a rather flat surface
density profile between 40 and 120 AU, while the inner cavity is consistent
with either a sharp drop of the 1.3 mm dust optical depth at about 42 AU or a
smooth inward decrease between 3 and 85 AU. (Abridge). Within 40 AU, the
observations constrain the amount of dust between 10^{-6} and 7 Earth masses,
where the minimum and maximum limits are set by the near-IR SED modeling and by
the mm-wave observations of the dust emission respectively. In addition, we
confirm the discrepancy in the outer disk radius inferred from the dust and
gas, which corresponds to 150 AU and 900 AU respectively. We cannot reconcile
this difference by adopting an exponentially tapered surface density profile as
suggested for other systems, but we instead suggest that the gas surface
density in the outer disk decreases less steeply than that predicted by model
fits to the dust continuum emission. The lack of continuum emission at radii
lager than 120 AU suggests a drop of at least a factor of 5 in the dust-to-gas
ratio, or in the dust opacity. We show that a sharp dust opacity drop of this
magnitude is consistent with a radial variation of the grain size distribution
as predicted by existing grain growth models.Comment: Accepted for publication on ApJ, 13 pages, 11 figure
CARMA interferometric observations of 2MASS J044427+2512: the first spatially resolved observations of thermal emission of a brown dwarf disk
We present CARMA 1.3 mm continuum data of the disk surrounding the young
brown dwarf 2MASS J044427+2512 in the Taurus molecular cloud. The high angular
resolution of the CARMA observations (0.16 arcsec) allows us to spatially
resolve for the first time the thermal emission from dust around a brown dwarf.
We analyze the interferometric visibilities and constrain the disk outer radius
adopting disk models with power-law radial profiles of the dust surface
density. In the case of a power-law index equal to or lower than 1, we obtain a
disk radius in the range of about 15 - 30 AU, while larger disks are inferred
for steeper radial profiles. By combining this information on the disk spatial
extent with the sub-mm spectral index of this source we find conclusive
evidence for mm-sized grains, or larger, in this brown dwarf disk. We discuss
the implications of our results on the models of dust evolution in
proto-planetary disks and brown dwarf formation.Comment: 14 pages, 3 figures, Accepted for publication in ApJ Letter
Identifying Anticyclonic Vortex Features Produced by the Rossby Wave Instability in Protoplanetary Disks
Several nearby protoplanetary disks have been observed to display large scale
crescents in the (sub)millimeter dust continuum emission. One interpretation is
that these structures correspond to anticyclonic vortices generated by the
Rossby wave instability within the gaseous disk. Such vortices have local gas
over-densities and are expected to concentrate dust particles with Stokes
number around unity. This process might catalyze the formation of
planetesimals. Whereas recent observations showed that dust crescent are indeed
regions where millimeter-size particles have abnormally high concentration
relative to the gas and smaller grains, no observations have yet shown that the
gas within the crescent region counter-rotates with respect to the
protoplanetary disk. Here we investigate the detectability of anticyclonic
features through measurement of the line-of-sight component of the gas velocity
obtained with ALMA. We carry out 2D hydrodynamic simulations and 3D radiative
transfer calculation of a protoplanetary disk characterized by a vortex created
by the tidal interaction with a massive planet. As a case study, the disk
parameters are chosen to mimic the IRS 48 system, which has the most prominent
crescent observed to date. We generate synthetic ALMA observations of both the
dust continuum and 12CO emission around the frequency of 345 GHz. We find that
the anticyclonic features of vortex are weak but can be detected if both the
source and the observational setup are properly chosen. We provide a recipe for
maximizing the probability to detect such vortex features and present an
analysis procedure to infer their kinematic properties.Comment: 14 pages, 8 figures, Accepted for publication in Astrophysical
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