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High Dynamic Range Imaging and Spectroscopy of Circumstellar Disks Alycia Weinberger (Carnegie Institution of Washington) With lots of input from: Aki.

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Presentation on theme: "High Dynamic Range Imaging and Spectroscopy of Circumstellar Disks Alycia Weinberger (Carnegie Institution of Washington) With lots of input from: Aki."— Presentation transcript:

1 High Dynamic Range Imaging and Spectroscopy of Circumstellar Disks Alycia Weinberger (Carnegie Institution of Washington) With lots of input from: Aki Roberge

2 10 6 yrs10 7 yrs10 8 yrs10 9 yrs  Persei Sun TW Hydrae Taurus, Ophiuchus star forming regions HyadesTucana Pleiades  Pic Planetary Formation Timeline Terrestrial planets form Era of heavy bombardment by comets CAI / Chondrule Formation Moon forming impact t0?t0? Giant planets form?

3  How and when do gas giant planets form (e.g. core-accretion or gravitational instability)?  How do disk materials segregate and move through disks? How Do Planets Form from Disks? These are questions that involve GAS and DUST!

4 1. To distinguish gas giant and terrestrial planet regions, need spatial resolution of ~1 AU (on GAS and DUST) 1 AU at 150 pc = 7 mas  Diffraction limited 20 m at < 650 nm 2. To actually see the disk at 1 AU, need high contrast between dust scattering and instrumental diffraction/scattering “Requirements”

5 T Tauri Disks with Gaps 10 mas resolution (ALMA or 2x worse than 20 m at 500 nm) Hydrodynamic simulation of 1 M Jup planet opening gap at 5 AU (Wolf et al. 2002)

6 ALMA-VLST Synergy  Break Albedo/Optical Depth Degeneracy  Dust Composition (Grain Size and Growth)  Molecular (ALMA) and Atomic (VLST) Gas Composition [stay tuned] From combination of millimeter emission and optical scattered light on similar spatial scales Watch planet formation at 1-5 AU at the distance to Taurus!

7 T Tauri Contrast Ratios: Dust TW Hydrae Star: R = 9.8 mag Face on Disk at 20 AU:  14 mag/arcsec 2 Future: Same contrast at 1 AU? (Krist et al. 2000 and Roberge et al. 2003)

8 Gas content can distinguish evolved from primordial material Sensitive line-of-sight UV spectroscopy (FUSE and STIS) For Example: AB Aur (~1 Myr old): ISM-like CO/ H 2  primordial  Pic (~15 Myr old): high CO/H 2  comets Lecavalier des Etangs et al. 2001; Roberge et al. 2000, 2001, 2002

9 UV Sensitively Traces Gas  N(H 2 ) <= 10 18 cm -2  N(CO) = (6.3 ± 0.3) x 10 14 cm -2  CO/H 2 > 6 x 10 -4  CO would be destroyed in < 200 yr  CO must be from planetesimals orbiting several tens of AU from star

10 H/a ≈ 0.18 a 2/7 20 m telescope at =150 nm  1.5 mas resln  0.23 AU at 150 pc H=0.25 AU at a=1.5 AU 1.5 AU Gas/Dust Ratio Relevant to: Controlling magnetospheric accretion Controlling elemental enrichment Structure of Disks From Gas Resonant Scattering

11 Vertical Disk Profile (  Pic) Arcsec (from midplane) Intensity (Brandeker et al. 2003) Want to do this: At distance to Taurus (150 pc) For UV ground-state electronic transitions (e.g. OI, CI, SI, SiI, FeI …)

12  How do terrestrial planets get their volatiles?  What is the relationship between giant planets and giant impacts? How Do Planets Interact With Their Disks?

13 Current State of the Art - High Contrast Imaging  High contrast imaging available only from HST: This is the only way to see dust very close to stars! Smith & Terrile (1984) Schneider & Weinberger (2004)

14 Disk Structure as Evidence for Low Mass Planets For optically thin disks and albedo ≈ 0.5: Integrated scattered light ≈ L IR / L * (Kuchner & Holman 2003)

15 5 Myr - HD 141569 NICMOSSTIS ACS (Weinberger et al. 1999, 2003; Augereau et al. 1999; Mouillet et al. 2001; Clampin et al. 2003) L IR / L * = 8 x 10 -3

16 8 Myr - HR 4796A 24  m emission (Koerner et al. 1998, ApJL) Visual reflection (Schneider et al. 2004, in prep) L IR / L * = 5 x 10 -3

17 12 Myr -  Pictoris Z (AU) Multiple Warps! STIS, Heap et al. (2000) Keck, Weinberger et al. (2003) L IR / L * = 2.5 x 10 -3

18 200 Myr - Fomalhaut  central cavity cleared of 90% of its dust  clump or arc produced by dust trapped in resonance with large planet 450  m Holland et al. 2003, ApJ 850  m L IR / L * = 1 x 10 -4

19 350 Myr - Vega (  Lyrae) Wilner et al. 2002 Koerner et al. 2001 Millimeter Emission L IR /L * = 2.5 x 10 -5

20 4.5 Gyr - Sun Zodiacal Light Albedo (~1  m): 0.2 Surface Density: r –0.4 Origin: Cometary & Asteroidal (75/25-50/50) T~230 K [286 K r –0.467 L 0.234 (DIRBE)] a~100  m L IR /L  =10 –7 Smooth component + bands (asteroidal, resonance trapped) (eg. Kelsall et al., ApJ,1998)

21 Delivery of Volatiles  Where are the ices (particularly water ice) in disks?  Where is the “snow line?”  Watch era of heavy bombardment (Clark & McCord 1980)

22 Spatially Resolved Dust Spectroscopy Example: TW Hya, but want to do this for optically thin disks Albedo as a function of location: What is the collision versus aging rate? Roberge et al.: See Poster!

23 Bottom Line  Possibility for enormous progress in spatially resolved UV-O spectroscopy to look for:  Gas density, dynamics and location as function of time (when do planets form)  High excitation atomic lines formed in shocks or X-wind (how do planets form)  Water and methane ices (near-IR) as function of location in disk (how do planets form and get their volatiles)

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