Deep HST/FOC Imaging of the Central Density Cusp of the Globular Cluster M15

Abstract

Using the Faint Object Camera on the repaired Hubble Space Telescope, we have observed two fields in the globular cluster M15:\ the central density cusp, and a field at r = 20''. These are the highest-resolution images ever taken of this cluster's dense core, and are the first to probe the distribution of stars well below the main-sequence turnoff. After correction for incompleteness, we measure a logarithmic cusp slope (d log sigma / d log r) of -0.70 +/- 0.05 (1-sigma) for turnoff ( ~ 0.8 Msun ) stars over the radial range from 0secspt3 to 10''; this slope is consistent with previous measurements. We also set an approximate upper limit of ~ 1\secspt5 (90% confidence limit) on the size of any possible constant-surface-density core, but discuss uncertainties in this limit that arise from crowding corrections. We find that fainter stars in the cusp also have power-law density profiles:\ a mass group near 0.7 Msun has a logarithmic slope of -0.56 +/- 0.05 (1-sigma) over the radial range from 2'' to 10''. Taken together, the two slopes are not well matched by the simplest core-collapse or black-hole models. We also measure a mass function at r = 20'', outside of the central cusp. Both of the FOC fields show substantial mass segregation, when compared with a mass function measured with the WFPC2 at r = 5'. In comparing the overall mass functions of the two FOC fields and the r=5' field, we find that the radial variation of the mass function is somewhat less than that predicted by a King-Michie model of the cluster, but greater than that predicted by a Fokker-Planck model taken from the literature.