Results from the Keck Interferometer Commissioning YSO Project Rafael Millan-Gabet Caltech/Michelson Science Center Collaboration: PIs: John Monnier (U.

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Presentation transcript:

Results from the Keck Interferometer Commissioning YSO Project Rafael Millan-Gabet Caltech/Michelson Science Center Collaboration: PIs: John Monnier (U. of Michigan), RMG Int. Team Lead: Rachel Akeson (Caltech/MSC) The KI JPL Team The KI WMKO Team Keck Science Meeting September The YSO Shared-Risk Project: ( , papers coming out now) Use the KI in V2 mode, to spatially resolve in the NIR the disks around a sample of well known young stars of various types (HAeBe, T Taus, FU Oris).

The KI and the Technique Current V2 mode: NIR interferometry w. the 2 Keck telescopes. (D=10m, AO-equipped, B=85m) Kband resolution: /B = 5mas or 100pc. Create fringes between the 2 Kecks and measure their amplitude … But: no fringe phase (due to atmosphere) only a few uv points V(u,v)  (u,v)

Example of Method LkHa101, Tuthill 2001 Assume a reasonable & simple model (e.g. star + Gaussian or ring brightness); obtain relative fluxes from SED decomposition; fit the V2 data to extract key morphology parameters of source of NIR excess (size, shape …): also, do hypothesis testing of realistic disk models. Excess K-band flux Ring D = mas. = AU

Why bother? KI resolution in context: HST/WFPC2 (C. Burrows STScI)

KI Results on Herbig Ae/Be Objects Monnier et al. 2005, ApJ, 624, well selected objects spanning B0 - A9. Established a tight size-L relation for HAe and late HBe, confirming earlier interferometer results (IOTA,PTI), and consistent with recently proposed “puffed-up” inner wall disk models (Natta 2001, Dullemond 2001). As previously pointed out (Monnier 2002, Eisner 2003,04), (most) earlier types are undersized w.r.t. these models, indicating some gas optical depth inside inner dust cavity.

KI Results on T Tauri Objects Akeson et al. 2005, accepted by ApJ 7 objects w. a range of disk properties (excess, Ha width). Inner wall models have been extended to T Tauri objects (to explain NIR excesses & 1st KI result - DG Tau, Colavita 2003) BUT adding accretion shock luminosity as central heating source (Muzerolle 2003, D’Alessio 2004). KI NIR sizes are consistent w. this picture, though require a range of inner wall conditions (opt. thin vs. thick dust; sublimation T). Perhaps lower accretion rate objects are more evolved, and their larger NIR sizes indicate inner disk dissipation by e.g. photoevaporation.

KI Results on FU Ori Objects Millan-Gabet et al. 2005, submitted to ApJ Interesting test case for models of accretion disks, since post-outburst emission is dominated by the disk. PTI, IOTA, VLTI observations of FU Ori itself confirmed expectations from standard single power law disk models (Malbet 1998, 2005). 3 KI objects VERY resolved. NOT consistent w. standard disk models. Proposed interpretation: “contamination” by flux coming from large scales (e.g. scattering by several AU structure, outer disk or envelope). If confirmed, compromises the notion to use the best known FU Oris for clean tests of disk theories …

Conclusions  The KI YSO program has produced interesting new results in the area of young pre-planetary disks (see also results by Eisner, Boden, Schaefer, Danchi).  Particularly for HAeBe objects (many already observed), next major progress will likely come from new instrumental capabilities: more wavelengths (KI, CHARA, VLTI); multi-baselines capabilities (IOTA3, CHARA, VLTI, KI?) … and object-by-object detailed modelling.  The KI is functioning well and is open for observing in NIR V2 mode.  Ask what it can do for you, and use it!