Saturday, July 11, 2009

Adaptive Optics Reveals Strange Dynamics in Ultra-Compact Star-forming Region

Figure 1. Velocity (km s−1) for the principal component of the Br line in each NIFS spaxel derived from the data with a Gaussian fit to the line profile. The mean Br velocity (VLSR = −62.5 km s−1) of the principal component has been removed from the map. The bipolar structure does not line up with any known point source, and the axis does not align with the direction of the large scale ionized flow detected at radio wavelengths. The peak relative velocities are −24 km s−1 and +31 km s−1, but the color map is “stretched” slightly to show smaller velocities.

Figure 2. K−band spectrum extracted from the central 2.5 arcsecond diameter of the NIFS field-of-view.

Using the Altair adaptive optics system with the Gemini Near-Infrared Spectrograph (NIFS) on Gemini North, a US/Australian team have obtained unprecedented high-spatial resolution integral field spectra of the Ultra-Compact H II Region K3-50A. The study reveals never-before-seen morphology and kinematics within this complex region of star formation (see Figure 1).

The team of Robert Blum (NOAO, Gemini Science Center) and Peter McGregor (Australian National University), observed the 3 arcsecond NIFS field at the core of the region, (covering 0.1 parsec at the object’s estimated distance of 7 kiloparsecs), and found sharp density variations that are thought to result from the action of a high mass central source radiation field and stellar wind on its birth cocoon and immediate surroundings. The observations were made at the Fredrick C. Gillett, Gemini North telescope on Mauna Kea, Hawai‘i in July of 2006.

The high angular resolution of the data (~0.2 arcsecond), moderate spectral resolution (approximately R = 5200), and detection of multiple spectral lines (Brγ, He I, [Fe III], [Kr III], [Se IV] and H2) allowed a detailed analysis of K3-50A (see Figure 2), including resolving ionization structure in the HII region as a function of position. Among the findings of this analysis is a bipolar kinematic feature that is not symmetric about any detected point source or ionized outflow seen in earlier radio continuum and recombination line studies. Several possibilities exist to explain the feature. It may be that a lower mass protostar is associated with the central star of K3-50A and its protostellar outflow is being ionized by the hot central source. Alternately, the bipolar flow may be the origin of a large-scale outflow seen in the radio which is re-directed by the material surrounding the compact central source.

K3-50A has a long history of observations that have spanned the spectrum from optical to radio (though the central source itself is highly obscured at optical wavelengths). The Gemini observations consist of near-infrared K-band spectra over NIFS’s ~3x3 arcsecond field which is sliced into 29x69 rectangular spatial pixels (spaxels) for a datacube of 2,001 elements. While this data cube has provided a detailed look at the nebular structure on a fine spatial scale, the central source itself remains a mystery. The putative massive young star is still veiled by the intense nebular continuum arising in its circumstellar environment: even with adaptive optics, no photospheric features of the star were detected.

The paper has been accepted for publication in the Astrophysical Journal and is available as a pre-print on astro-ph at: http://arxiv.org/abs/0906.2793.