The two young star disks in the central parsec of the galaxy: Properties, dynamics, and formation

We report the definite spectroscopic identification of similar or equal to 40 OB supergiants, giants, and main-sequence stars in the central parsec of the Galaxy. Detection of their absorption lines has become possible with the high spatial and spectral resolution and sensitivity of the adaptive optics integral field spectrometer SPIFFI/SINFONI on the ESO VLT. Several of these OB stars appear to be helium- and nitrogen-rich. Almost all of the similar or equal to 80 massive stars now known in the central parsec (central arcsecond excluded) reside in one of two somewhat thick ((vertical bar h vertical bar/R) similar or equal to 0.14) rotating disks. These stellar disks have fairly sharp inner edges (R similar or equal to 1 '') and surface density profiles that scale as R-2. We do not detect any OB stars outside the central 0.5 pc. The majority of the stars in the clockwise system appear to be on almost circular orbits, whereas most of those in the counterclockwise disk appear to be on eccentric orbits. Based on its stellar surface density distribution and dynamics, we propose that IRS 13E is an extremely dense cluster (rho(core) greater than or similar to 3 x 10(8) M-circle dot pc(-3)) that has formed in the counterclockwise disk. The stellar contents of both systems are remarkably similar, indicating a common age of similar or equal to 6 +/- 2 Myr. The K-band luminosity function of the massive stars suggests a top-heavy mass function and limits the total stellar mass contained in both disks to similar or equal to 1.5 x 10(4) M-circle dot. Our data strongly favor in situ star formation from dense gas accretion disks for the two stellar disks. This conclusion is very clear for the clockwise disk and highly plausible for the counterclockwise system.