1. Observations of Disks around Young Stellar Objects
G. Duchêne & F. Ménard (Obs. Grenoble)

2. G. Duchêne - Structure Formation in the Universe - May 2007
Goals of this talk
Consider as wide a range of datasets as possible in 30 minutes!
Will skip some very exciting aspects
Discussion of selected physical aspects
Leave out gas and chemistry
Persuade you that we can now constrain some physical processes
Yet many open questions remain…
G. Duchêne - Structure Formation in the Universe - May 2007

3. G. Duchêne - Structure Formation in the Universe - May 2007
Outline
General motivation
Observational methods
Disks in the context of star formation
Disks in the context of planet formation
Debris disks: after planets formed
Summary and perspectives
G. Duchêne - Structure Formation in the Universe - May 2007

4. G. Duchêne - Structure Formation in the Universe - May 2007
General Motivation
G. Duchêne - Structure Formation in the Universe - May 2007

5. Why do we care about disks?
A natural outcome of
star formation
G. Duchêne - Structure Formation in the Universe - May 2007

6. Why do we care about disks?
Planetary system
factories
A natural outcome of
star formation
G. Duchêne - Structure Formation in the Universe - May 2007

7. Expected physical processes (I)
Influence of central star/environment
Disk lifetime
Total mass reservoir
Overall structure
Disk dispersal mechanism
Viscous dissipation of angular momentum
Photo-ionization
Dynamical dispersal (companion)
G. Duchêne - Structure Formation in the Universe - May 2007

8. Expected physical processes (II)
Substructure formation
Spiral arms (instabilities, planets)
Gap openings (planets)
Dust evolution
Grain growth
Radial migration
Vertical sedimentation
Change in grain structure
G. Duchêne - Structure Formation in the Universe - May 2007

9. G. Duchêne - Structure Formation in the Universe - May 2007
Observations of disks
G. Duchêne - Structure Formation in the Universe - May 2007

10. Unresolved datasets: SEDs
The simplest approach: gather the energy and try to invert to disk structure
Flared disks in most cases
Flat
Flared
Chiang & Goldreich (1997)
Dullemond et al. (2007)
G. Duchêne - Structure Formation in the Universe - May 2007

11. Unresolved datasets: SEDs
Useful approach for statistical purposes
Can be dangerous on an object-to-object basis
Need for resolved datasets!
Burrows et al. (1996)
All Taurus
CTTS
D’Alessio et al. (2001)
G. Duchêne - Structure Formation in the Universe - May 2007

12. G. Duchêne - Structure Formation in the Universe - May 2007
Resolved datasets
A single image provides key parameters:
Outer radius, position angle
Inclination (sometimes)
Optical depth (sometimes)
Not a normal
disk
Guilloteau et al. (1999)
Bertout et al. (1998)
G. Duchêne - Structure Formation in the Universe - May 2007

13. G. Duchêne - Structure Formation in the Universe - May 2007
Resolved datasets
grain size
VLT/VISIR
composition
structure
Interf.
Spitzer
mass
All probe different dust populations
G. Duchêne - Structure Formation in the Universe - May 2007

14. G. Duchêne - Structure Formation in the Universe - May 2007
Resolved datasets
VLT/VISIR
Interf.
Spitzer
Need for complementary complex RT models
G. Duchêne - Structure Formation in the Universe - May 2007

15. Disks and Star Formation
G. Duchêne - Structure Formation in the Universe - May 2007

16. Disks and central object mass
How universal is star formation?
Probe disk presence through IR excess
Overall fraction up to 90% (in  Oph)
Best studied population: the ONC
disks at all masses ( M)
Slight deficit at
low mass end?
Hillenbrand et al. (1998)
G. Duchêne - Structure Formation in the Universe - May 2007

17. Disks and central object mass
Detection is harder around VLMS/BD because of cooler Teff
BDs: 40-75% up to ~5 Myr at least
No substantial difference with stars
Jayawardhana et al. (2003)
Liu et al. (2003)
G. Duchêne - Structure Formation in the Universe - May 2007

18. Disks and central object mass
Not only is disk frequency independent of mass, their structure is, too!
Hydrostatic (flared) passive disks
~0.1 M
~0.5 M
~2 M
IRAS
HK Tau
PDS 144
Glauser et al. (2007)
McCabe et al. (2007)
Perrin et al. (2007)
G. Duchêne - Structure Formation in the Universe - May 2007

19. Disks and central object mass
The special case of high-mass stars:
Aligned (rotating) methanol masers, but not so clear Norris et al. (1993), De Buizer et al. (2003)
Wide-angle outflows
A huge ‘silhouette disk’
Difficult to conclude yet
Too far away
Evolving too fast
20000 AU
M17
Chini et al. (2004)
G. Duchêne - Structure Formation in the Universe - May 2007

20. Disks and orientation of stars
Taurus molecular cloud = series of filaments orthogonal to B field
So are individual pre-stellar cores
CO map
Prestellar cores
Hartmann (2002)
G. Duchêne - Structure Formation in the Universe - May 2007

21. Disks and orientation of stars
Disks around T Tauri stars indicate the system’s symmetry axis
Systems are randomly oriented w.r.t. local magnetic field
What happened?
Non-magnetic collapse?
Ménard & Duchêne (2004)
G. Duchêne - Structure Formation in the Universe - May 2007

22. Disks and Planet Formation (overall disk properties)
G. Duchêne - Structure Formation in the Universe - May 2007

23. G. Duchêne - Structure Formation in the Universe - May 2007
Disks sizes and masses
Typical disk size ~ 200 AU
Compares well with Solar System
Large scatter around median value!
IRAS
HV Tau
~ 1100 AU
~ 40 AU
Stapelfeldt et al. (2003)
Kitamura et al. (2002)
Glauser et al. (2007)
G. Duchêne - Structure Formation in the Universe - May 2007

24. G. Duchêne - Structure Formation in the Universe - May 2007
Disks sizes and masses
Disk masses can be derived from thermal radio fluxes/maps
Uncertain dust opacities
Uncertain gas/dust ratio
Derived total masses:
Consistent with MMSN
Consistent with stability
Natta et al. (2000)
G. Duchêne - Structure Formation in the Universe - May 2007

25. G. Duchêne - Structure Formation in the Universe - May 2007
Disks sizes and masses
Radio interferometers (IRAM, OVRO) can resolve disks
Typical surface density ~1 100AU
Power law indices
Temperature law
Surface density
‘Flat’ MMSN-like disks
Good for planets!
But interpolation…
Dutrey et al. (1996)
G. Duchêne - Structure Formation in the Universe - May 2007

26. Disk asymmetries: large scales
Evidence for dynamical perturbation:
Companion, planet, high-mass disk?
What you see is NOT what you have… HD
AB Aur
Optically thin!
Grady et al. (2001)
Fukagawa et al. (2004)
Piétu et al. (2005)
G. Duchêne - Structure Formation in the Universe - May 2007

27. Disk asymmetries: gaps
Planets embedded in disks open ‘gaps’
Can these be observed?
Gap size < 1AU
High resolution + high contrast
ALMA? New generation AO?
Remember, however:
Spatial resolution remains an issue
Gaps may be partly filled in
G. Duchêne - Structure Formation in the Universe - May 2007

28. G. Duchêne - Structure Formation in the Universe - May 2007
Disk dissipation
Using disk counts in independent SFRs provides survival time of inner disk
Essentially nothing left after 10 Myr
No environment effect
OB vs T associations,
clusters
Large bodies may still
be present and hidden
Disk lifetime
Meyer et al. (2000)
G. Duchêne - Structure Formation in the Universe - May 2007

29. G. Duchêne - Structure Formation in the Universe - May 2007
Disk dissipation
Does disk dissipation depend on central object mass?
Spitzer surveys of UpSco (~5Myr)
G-B: 5 +/- 2 %
K0-M5: 19 +/- 3%
BDs: 37 +/- 9 %
Disk lifetime is longer for lower mass objects
Because of slower viscous timescale? }
Carpenter et al. (2005)
Scholtz et al. (2007)
G. Duchêne - Structure Formation in the Universe - May 2007

30. G. Duchêne - Structure Formation in the Universe - May 2007
Inner disk dispersal
Disks disappear after inner hole clearing
Evidence shows that disks dissipate inside-out in <105 yrs (viscous timescale)
AU material
Very few
transition objects
CoKu Tau 4
D’Alessio et al. (2005)
McCabe et al. (2006)
0.5-2 AU material
G. Duchêne - Structure Formation in the Universe - May 2007

31. G. Duchêne - Structure Formation in the Universe - May 2007
Inner disk dispersal
How long does the outer disk remain?
Spitzer searches for disk with only outer disk material (>5-10 AU)
Only a few percent of such objects
Outer disk falls below
detection threshold
in <~ 105 yrs
Too fast for viscosity?
Padgett et al. (2006)
G. Duchêne - Structure Formation in the Universe - May 2007

32. Disks and Planet Formation (dust properties)
G. Duchêne - Structure Formation in the Universe - May 2007

33. G. Duchêne - Structure Formation in the Universe - May 2007
Grain growth: mm view
First approach: SED slope (mm regime)
Typically, amax ~ few mm to few cm
Large
grains
Observed
distribution
of spectral
indices
Small
grains
D’Alessio et al. (2001)
Natta et al. (2007)
G. Duchêne - Structure Formation in the Universe - May 2007

34. Grain growth: silicates view
Silicate feature is size-dependent
Small (< 0.1 m) vs large grains (~1 m)
Larger grains do not contribute
Crystallinity produces sharp features
Kessler-Silacci et al. (2006)
G. Duchêne - Structure Formation in the Universe - May 2007

35. Grain growth: silicates view
Clear evolutionary sequence
Larger grains come together with higher grain crystallinity (above a threshold)
Higher crystallinity
Smaller grains
Kessler-Silacci et al. (2006)
Van Boekel et al. (2005)
G. Duchêne - Structure Formation in the Universe - May 2007

36. Grain growth: scattered light
Stellar photons can scatter off dust grains at the disk surface
Phenomenon depends on /a
Larger grains scatter preferentially forward, with a lower polarization rate
Images and polarization maps can be used to infer grain sizes
Up to amax ~ few m typically
Advantage: longer  probes deeper!!
G. Duchêne - Structure Formation in the Universe - May 2007

37. Grain growth: scattered light
Single power law size distribution
Increasingly more isotropic scattering
HK Tau images (increasingly ‘peakier’) reveal larger grains inside (up to 3-5 m)
VLT/AO
Keck/AO
Keck/AO
Keck
2.2 m
3.8 m
4.7 m
11.3 m
McCabe et al. (in prep)
McCabe et al. (2003)
G. Duchêne - Structure Formation in the Universe - May 2007

38. Grain growth: the big picture
Each aspect probes
A different region of disks
Different grain sizes/populations
In each case, analysis requires knowledge of additional information (radius, inclination, …)
Ideally, comparison all datasets to a single (complex) radiative transfer model
G. Duchêne - Structure Formation in the Universe - May 2007

39. Vertical sedimentation
If large grains disappear from the surface, thermal equilibrium is changed
Change in disk SED
Difficult to ascertain, however
Sedimentation
mimics a flat disk
Dullemond & Dominik et al. (2004)
G. Duchêne - Structure Formation in the Universe - May 2007

40. Vertical sedimentation
Confront mm regime and silicates
Can be convincing (if composition is well distributed throughout the disk)
IM Lup
Small grains
only
Small and
large grains
Pinte et al. (in prep)
G. Duchêne - Structure Formation in the Universe - May 2007

41. Vertical sedimentation
Confront mm regime and silicates
Can be convincing (if composition is well distributed throughout the disk)
IM Lup
Small and
large grains
Small grains
only
Small and
large grains
sedimentation
Pinte et al. (in prep)
G. Duchêne - Structure Formation in the Universe - May 2007

42. G. Duchêne - Structure Formation in the Universe - May 2007
Radial migration
Interferometry + spectroscopy (MIDI)
Silicate features a few AU from the star
Higher crystallinity!
Grain processing?
RY Tau (K1)
small
van Boekel
et al. (2004)
crystalline
Shegerer et al. (subm.)
G. Duchêne - Structure Formation in the Universe - May 2007

43. G. Duchêne - Structure Formation in the Universe - May 2007
Radial migration
Difficult to quantify differentiation
Many assumptions in analysis
Nonetheless, there is evidence that grain properties depend on radial distance to the star
However, we cannot prove that grains have migrated!
Crystallinization may be a local processing
G. Duchêne - Structure Formation in the Universe - May 2007

44. Further in time: debris disks
G. Duchêne - Structure Formation in the Universe - May 2007

45. G. Duchêne - Structure Formation in the Universe - May 2007
Debris disks: basics
Debris disks are the final stage in planet formation before zodiacal disks
Formed through collisions of solid bodies
They are optically thin
Easier to interpret
Harder to observe
SED is usually limited
Rough constraints only
Beichman et al. (2006)
G. Duchêne - Structure Formation in the Universe - May 2007

46. Debris disks: porosity, aggregates
With many independent observables, finer models can be tested
The AU Mic debris disk is made of (small) porous grains
porous
compact
Fitzgerald et al. (2007)
G. Duchêne - Structure Formation in the Universe - May 2007

47. Debris disks: porosity, aggregates
Another debris disk: HD
All observables cannot be explained simultaneously with spherical grains
Aggregates?
SED vs ?
Phase
function
Schneider et al. (2006)
G. Duchêne - Structure Formation in the Universe - May 2007

48. Summary and Perspectives
G. Duchêne - Structure Formation in the Universe - May 2007

49. G. Duchêne - Structure Formation in the Universe - May 2007
Summary
We have access to many types of complementary observations
Several physical processes can be (somewhat) constrained
Core collapse/fragmentation
Disk dissipation and inner hole clearing
Grain growth
Dust settling
Presence of planetesimals
G. Duchêne - Structure Formation in the Universe - May 2007

50. G. Duchêne - Structure Formation in the Universe - May 2007
Perspectives
More observations will come with future instrumentation (e.g., ALMA)
At this stage, we still need
Complex modeling/analysis of datasets
More multi-technique analysis
Tests of the basic processes in models
Wait for next talks, to get the theorists’ point of view!
G. Duchêne - Structure Formation in the Universe - May 2007