HCN and HCO+Observations of the Galactic Circumnuclear Disk

Abstract

We present high spatial resolution (5.1" x 2.7") OVRO millimeter array observations of HCN (J=1-0) and HCO+ (J=1-0) emission in the inner 3 pc of the galaxy. The HCN and HCO+ emission of the circumnuclear disk (CND) is distributed in a well-defined ring with a peak at a radius of 1.6pc. The HCO+/HCN emission ratio is typically ~0.4 but with significant variations. The HCN emission is well correlated with the H_2 emission at 2.12 microns both in the main emission lobes of the CND and also in four filaments. Multiple areas of interaction between the ionized gas and the CND are also seen - the western arm of the minispiral is spatially and kinematically consistent with being the ionized inner edge of the CND, and the northern arm may be connected to the CND northeastern extension. With the enhanced spatial resolution of the HCN map, we resolve numerous dense molecular gas cores within the CND with characteristic diameter of 7" (0.25pc). For 26 of the more isolated cores, we measure sizes, velocity widths, and integrated fluxes. We estimate three masses for each core: a virial mass, an optically thick mass, and a lower limit mass assuming optically thin HCN emission. The virial and optically thick masses are in good agreement with a typical mass of (2-3)x10^4 M_sun and a total CND gas mass of 10^6 M_sun. The internal densities implied by these core masses are on average (3-4)x10^7 cm^-3, high enough to be stable against tidal disruption from Sgr A* and the central stellar concentration. This tidal stability suggests a longer lifetime for the CND. The higher densities and masses within the cores might support star formation either in the CND itself or within a core infalling toward the inner parsec, thus providing a mechanism for the formation of the young stellar population in the inner arcseconds of the galaxy.