First results from VLTI near-infrared interferometry on high-mass young stellar objects

Due to the recent dramatic technological advances, infrared interferometry can now be applied to new classes of objects, resulting in exciting new science prospects, for instance, in the area of high-mass star formation. Although extensively studied at various wavelengths, the process through which massive stars form is still only poorly understood. For instance, it has been proposed that massive stars might form like low-mass stars by mass accretion through a circumstellar disk/envelope, or otherwise by coalescence in a dense stellar cluster. Therefore, clear observational evidence, such as the detection of disks around high-mass young stellar objects (YSOs), is urgently needed in order to unambiguously identify the formation mode of the most massive stars. After discussing the technological challenges which result from the special properties of these objects, we present first near-infrared interferometric observations, which we obtained on the massive YSO IRAS 13481-6124 using VLTI/AMBER infrared long-baseline interferometry and NTT speckle interferometry. From our extensive data set, we reconstruct a model-independent aperture synthesis image which shows an elongated structure with a size of ~ 13 x 19 AU, consistent with a disk seen under an inclination of - 45°. The measured wavelengthdependent visibilities and closure phases allow us to derive the radial disk temperature gradient and to detect a dust-free region inside of 9.5 AU from the star, revealing qualitative and quantitative similarities with the disks observed in low-mass star formation. In complementary mid-infrared Spitzer and sub-millimeter APEX imaging observations we detect two bow shocks and a molecular outflow, which are oriented perpendicular to the disk plane and indicate the presence of a bipolar outflow emanating from the inner regions of the system.

[1]  M. Wolfire,et al.  Conditions for the formation of massive stars , 1987 .

[2]  Vianak Naranjo,et al.  Near-infrared wavefront sensing for the VLT interferometer , 2008, Astronomical Telescopes + Instrumentation.

[3]  L. Testi,et al.  Infall of gas as the formation mechanism of stars up to 20 times more massive than the Sun , 2006, Nature.

[4]  G. Weigelt,et al.  Visual/infrared interferometry of Orion Trapezium stars: preliminary dynamical orbit and aperture synthesis imaging of the θ1 Orionis C system , 2007, astro-ph/0702462.

[5]  M. S. N. Kumar,et al.  Spitzer-IRAC GLIMPSE of high mass protostellar objects - II. SED modelling of a bona fide sample , 2009, 0901.2053.

[6]  M. Wolff,et al.  Two-dimensional Radiative Transfer in Protostellar Envelopes. I. Effects of Geometry on Class I Sources , 2003, astro-ph/0303479.

[7]  R. Indebetouw,et al.  Interpreting Spectral Energy Distributions from Young Stellar Objects. I. A Grid of 200,000 YSO Model SEDs , 2006, astro-ph/0608234.

[8]  S. Molinari,et al.  Search for massive protostellar candidates in the southern hemisphere. I. Association with dense gas , 2004, astro-ph/0412158.

[9]  J.-L. Lizon,et al.  MATISSE: perspective of imaging in the mid-infrared at the VLTI , 2006, Astronomical Telescopes + Instrumentation.

[10]  P. Goldreich,et al.  Spectral Energy Distributions of T Tauri Stars with Passive Circumstellar Disks , 1997, astro-ph/9706042.

[11]  David Mouillet,et al.  AMBER : Instrument description and first astrophysical results Special feature AMBER , the near-infrared spectro-interferometric three-telescope VLTI instrument , 2007 .

[12]  J. D. Monnier,et al.  The Near-Infrared Size-Luminosity Relations for Herbig Ae/Be Disks , 2005, astro-ph/0502252.

[13]  K. Menten,et al.  A hot compact dust disk around a massive young stellar object , 2010, Nature.

[14]  Romain G. Petrov,et al.  A binary engine fuelling HD 87643's complex circumstellar environment , 2009 .

[15]  John D. Monnier,et al.  2006 interferometry imaging beauty contest , 2006, SPIE Astronomical Telescopes + Instrumentation.

[16]  Keiichi Ohnaka,et al.  Detection of an Inner Gaseous Component in a Herbig Be Star Accretion Disk: Near- and Mid-Infrared Spectrointerferometry and Radiative Transfer modeling of MWC 147 , 2007, 0711.4988.

[17]  S. Lumsden,et al.  The origin of mid-infrared emission in massive young stellar objects: multi-baseline VLTI observations of W33A , 2009, 0912.2869.

[18]  R. Indebetouw,et al.  GLIMPSE. I. An SIRTF Legacy Project to Map the Inner Galaxy , 2003, astro-ph/0306274.

[19]  John D. Monnier,et al.  An interferometry imaging beauty contest , 2004, SPIE Astronomical Telescopes + Instrumentation.

[20]  G. P. Weigelt,et al.  Modified astronomical speckle interferometry “speckle masking” , 1977 .

[21]  Gerd Weigelt,et al.  Iterative image reconstruction from the bispectrum , 1993 .

[22]  Outflows from Massive Young Stellar Objects as Seen with the Infrared Array Camera , 2006, astro-ph/0603404.

[23]  A. Labeyrie Attainment of diffraction limited resolution in large telescopes by Fourier analysing speckle patterns in star images , 1970 .

[24]  R. Klein,et al.  The Formation of Massive Star Systems by Accretion , 2009, Science.

[25]  K. Menten,et al.  The Formation of Massive Stars , 1998, Proceedings of the International Astronomical Union.

[26]  Search for massive protostar candidates in the southern hemisphere. II. Dust continuum emission , 2005, astro-ph/0510422.

[27]  C. McKee,et al.  Massive star formation in 100,000 years from turbulent and pressurized molecular clouds , 2002, Nature.

[28]  S. Quanz,et al.  Mid-infrared interferometry of massive young stellar objects. I. VLTI and Subaru observations of the , 2009, 0907.0445.

[29]  M. M. Colavita,et al.  FIRST L-BAND INTERFEROMETRIC OBSERVATIONS OF A YOUNG STELLAR OBJECT: PROBING THE CIRCUMSTELLAR ENVIRONMENT OF MWC 419 , 2009, 0907.4809.

[30]  Karl-Heinz Hofmann,et al.  2008 imaging beauty contest , 2008, Astronomical Telescopes + Instrumentation.

[31]  M. Schoeller,et al.  Tracing the young massive high-eccentricity binary system Theta 1 Orionis C through periastron passage , 2009, 0902.0365.

[32]  R. L. Akeson,et al.  Spectrally Dispersed K-Band Interferometric Observations of Herbig Ae/Be Sources: Inner Disk Temperature Profiles , 2006, astro-ph/0611447.