123 research outputs found
A tunnel and a traffic jam: How transition disks maintain a detectable warm dust component despite the presence of a large planet-carved gap
We combined hydrodynamical simulations of planet-disk interactions with dust
evolution models that include coagulation and fragmentation of dust grains over
a large range of radii and derived observational properties using radiative
transfer calculations. We studied the role of the snow line in the survival of
the inner disk of transition disks. Inside the snow line, the lack of ice
mantles in dust particles decreases the sticking efficiency between grains. As
a consequence, particles fragment at lower collision velocities than in regions
beyond the snow line. This effect allows small particles to be maintained for
up to a few Myrs within the first astronomical unit. These particles are
closely coupled to the gas and do not drift significantly with respect to the
gas. For lower mass planets (1), the pre-transition appearance
can be maintained even longer because dust still trickles through the gap
created by the planet, moves invisibly and quickly in the form of relatively
large grains through the gap, and becomes visible again as it fragments and
gets slowed down inside of the snow line. The global study of dust evolution of
a disk with an embedded planet, including the changes of the dust aerodynamics
near the snow line, can explain the concentration of millimetre-sized particles
in the outer disk and the survival of the dust in the inner disk if a large
dust trap is present in the outer disk. This behaviour solves the conundrum of
the combination of both near-infrared excess and ring-like millimetre emission
observed in several transition disks.Comment: Accepted for publication in A&A (including acknowledgments
An Inner Disk in the Large Gap of the Transition Disk SR 24S
We report new Atacama Large Millimeter/sub-millimeter Array (ALMA) Band 3
observations at 2.75 mm of the TD around SR 24S with an angular resolution of
0.11'' 0.09'' and a peak signal-to-noise ratio of . We
detect an inner disk and a mostly symmetric ring-like structure that peaks at
0.32'', that is 37 au at a distance of 114.4 pc. The full
width at half maximum of this ring is 28 au. We analyze the observed
structures by fitting the dust continuum visibilities using different models
for the intensity profile, and compare with previous ALMA observations of the
same disk at 0.45 mm and 1.30 mm. We qualitatively compare the results of these
fits with theoretical predictions of different scenarios for the formation of a
cavity or large gap. The comparison of the dust continuum structure between
different ALMA bands indicates that photoevaporation and dead zone can be
excluded as leading mechanisms for the cavity formation in SR 24S disk, leaving
the planet scenario (single or multiple planets) as the most plausible
mechanism. We compared the 2.75 mm emission with published (sub-)centimeter
data and find that the inner disk is likely tracing dust thermal emission. This
implies that any companion in the system should allow dust to move inwards
throughout the gap and replenish the inner disk. In the case of one single
planet, this puts strong constraints on the mass of the potential planet inside
the cavity and the disk viscosity of about 5 and
, respectively.Comment: Accepted to Ap
The 2008-2009 outburst of the young binary system Z CMa unraveled by interferometry with high spectral resolution
Z CMa is a young binary system consisting of an Herbig primary and a FU Ori
companion. Both components seem to be surrounded by active accretion disks and
a jet was associated to the Herbig B0. In Nov. 2008, K. Grankin discovered that
Z CMa was exhibiting an outburst with an amplitude larger than any photometric
variations recorded in the last 25 years. To study the innermost regions in
which the outburst occurs and understand its origin, we have observed both
binary components with AMBER/VLTI across the Br{\gamma} emission line in Dec.
2009 in medium and high spectral resolution modes. Our observations show that
the Herbig Be, responsible for the increase of luminosity, also produces a
strong Br{\gamma} emission, and they allow us to disentangle from various
origins by locating the emission at each velocities through the line.
Considering a model of a Keplerian disk alone fails at reproducing the
asymmetric spectro-astrometric measurements, suggesting a major contribution
from an outflow.Comment: To be published in the proceedings of the SPIE'2010 conference on
"Optical and Infrared Interferometry II
Intricate visibility effects from resolved emission of young stellar objects: the case of MWC158 observed with the VLTI
In the course of our VLTI young stellar object PIONIER imaging program, we
have identified a strong visibility chromatic dependency that appeared in
certain sources. This effect, rising value of visibilities with decreasing
wavelengths over one base, is also present in previous published and archival
AMBER data. For Herbig AeBe stars, the H band is generally located at the
transition between the star and the disk predominance in flux for Herbig AeBe
stars. We believe that this phenomenon is responsible for the visibility rise
effect. We present a method to correct the visibilities from this effect in
order to allow "gray" image reconstruction software, like Mira, to be used. In
parallel we probe the interest of carrying an image reconstruction in each
spectral channel and then combine them to obtain the final broadband one. As an
illustration we apply these imaging methods to MWC158, a (possibly Herbig) B[e]
star intensively observed with PIONIER. Finally, we compare our result with a
parametric model fitted onto the data.Comment: 14 pages, 7 figure
Submillimeter emission associated with candidate protoplanets
We present the discovery of a spatially unresolved source of sub-millimeter
continuum emission ( m) associated with a young planet, PDS
70 c, recently detected in H emission around the 5 Myr old T Tauri star
PDS 70. We interpret the emission as originating from a dusty circumplanetary
disk with a dust mass between and Earth
masses. Assuming a standard gas-to-dust ratio of 100, the ratio between the
total mass of the circumplanetary disk and the mass of the central planet would
be between . Furthermore, we report the discovery of another
compact continuum source located South-West of a second
known planet in this system, PDS 70 b, that was previously detected in
near-infrared images. We speculate that the latter source might trace dust
orbiting in proximity of the planet, but more sensitive observations are
required to unveil its nature.Comment: Accepted for publication on ApJ
Mapping the Complex Kinematic Substructure in the TW Hya Disk
We present ALMA observations of CO and CS emission from
the disk around TW~Hydrae. Both molecules trace a predominantly Keplerian
velocity structure, although a slowing of the rotation velocity is detected at
the outer edge of the disk beyond ~au in CO emission. This was
attributed to the enhanced pressure support from the gas density taper near the
outer edge of the disk. Subtraction of an azimuthally symmetric background
velocity structure reveals localized deviations in the gas kinematics traced by
each of the molecules. Both CO and CS exhibit a `Doppler flip' feature,
centered nearly along the minor axis of the disk ({\rm PA} \sim 60\degr) at a
radius of 1\farcs35, coinciding with the large gap observed in scattered
light and mm~continuum. In addition, the CO emission, both through changes in
intensity and its kinematics, traces a tightly wound spiral, previously seen
with higher frequency CO observations (Teague et al., 2019). Through
comparison with linear models of the spiral wakes generated by embedded
planets, we interpret these features in the context of interactions with a
Saturn-mass planet within the gap at a position angle of {\rm PA} = 60\degr,
consistent with the theoretical predictions of (Mentiplay et al. 2019). The
lack of a corresponding spiral in the CS emission is attributed to the strong
vertical dependence on the buoyancy spirals which are believed to only grow in
the atmospheric of the disk, rather than those traced by CS emission.Comment: Accepted to Ap
Evolution of protoplanetary disks from their taxonomy in scattered light: Group I vs. Group II
High-resolution imaging reveals a large morphological variety of
protoplanetary disks. To date, no constraints on their global evolution have
been found from this census. An evolutionary classification of disks was
proposed based on their IR spectral energy distribution, with the Group I
sources showing a prominent cold component ascribed to an earlier stage of
evolution than Group II. Disk evolution can be constrained from the comparison
of disks with different properties. A first attempt of disk taxonomy is now
possible thanks to the increasing number of high-resolution images of Herbig
Ae/Be stars becoming available. Near-IR images of six Group II disks in
scattered light were obtained with VLT/NACO in Polarimetric Differential
Imaging, which is the most efficient technique to image the light scattered by
the disk material close to the stars. We compare the stellar/disk properties of
this sample with those of well-studied Group I sources available from the
literature. Three Group II disks are detected. The brightness distribution in
the disk of HD163296 indicates the presence of a persistent ring-like structure
with a possible connection with the CO snowline. A rather compact (less than
100 AU) disk is detected around HD142666 and AK Sco. A taxonomic analysis of 17
Herbig Ae/Be sources reveals that the difference between Group I and Group II
is due to the presence or absence of a large disk cavity (larger than 5 AU).
There is no evidence supporting the evolution from Group I to Group II. Group
II are not evolved version of the Group I. Within the Group II disks, very
different geometries (both self-shadowed and compact) exist. HD163296 could be
the primordial version of a typical Group I. Other Group II, like AK Sco and
HD142666, could be smaller counterpart of Group I unable to open cavities as
large as those of Group I.Comment: 16 pages, 7 figures, published by A&
The Disk Substructures at High Angular Resolution Project (DSHARP). IV. Characterizing Substructures and Interactions in Disks around Multiple Star Systems
To characterize the substructures induced in protoplanetary disks by the interaction between stars in multiple systems, we study the 1.25 mm continuum and the 12CO(J = 2–1) spectral line emission of the triple systems HT Lup and AS 205, at scales of ≈5 au, as part of the Disk Substructures at High Angular Resolution Project (DSHARP). In the continuum emission, we find two symmetric spiral arms in the disk around AS 205 N, with a pitch angle of 14°, while the southern component AS 205 S, itself a spectroscopic binary, is surrounded by a compact inner disk and a bright ring at a radius of 34 au. The 12CO line exhibits clear signatures of tidal interactions, with spiral arms, extended arc-like emission, and high velocity gas, possible evidence of a recent close encounter between the disks in the AS 205 system, as these features are predicted by hydrodynamic simulations of flyby encounters. In the HT Lup system, we detect continuum emission from all three components. The primary disk, HT Lup A, also shows a two-armed symmetric spiral structure with a pitch angle of 4°, while HT Lup B and C, located at 25 and 434 au in projected separation from HT Lup A, are barely resolved with ~5 and ~10 au in diameter, respectively. The gas kinematics for the closest pair indicates a different sense of rotation for each disk, which could be explained by either a counter rotation of the two disks in different, close to parallel, planes, or by a projection effect of these disks with a close to 90° misalignment between them
Variable Outer Disk Shadowing Around the Dipper Star RX J1604.3-2130
Low brightness dips have recently been observed in images of protoplanetary disks, and they are believed to be shadows by the inner disk. We present VLT/SPHERE polarimetric differential imaging of the transition disk around the dipper star RX J1604.3-2130. We gathered 11 epochs that cover a large temporal baseline, to search for variability over timescales of years, months, weeks, and days. Our observations unambiguously reveal two dips along an almost face-on narrow ring (with a width of ∼20 au), and the location of the peak of this ring is at ∼65 au. The ring lies inside the ring-like structure observed with ALMA, which peaks at ∼83 au. This segregation can result from particle trapping in pressure bumps, potentially due to planet(s). We find that the dips are variable, both in morphology and in position. The eastern dip, at a position angle (PA) of ∼83.°7 ±13.°7, has an amplitude that varies between 40% to 90%, and its angular width varies from 10° to 34°. The western dip, at a PA of ∼265.°90 ±13.°0, is more variable, with amplitude and width variations of 31% to 95% and 12° to 53°, respectively. The separation between the dips is 178.°3 ±14.°5, corresponding to a large misalignment between the inner and outer disks, supporting the classification of J1604 as an aperiodic dipper. The variability indicates that the innermost regions are highly dynamic, possibly due to a massive companion or to a complex magnetic field topology.</p
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