Composition of the galactic center star cluster: Population analysis from adaptive optics narrow band spectral energy distributions

TL;DR

This study introduces a new narrow band spectral energy distribution method to classify stars in the galactic center, enabling deeper and more efficient population analysis of early and late type stars in the dense cluster.

Contribution

A novel AO-assisted spectral energy distribution technique for star classification in the galactic center, improving depth and efficiency over previous spectroscopic methods.

Findings

Classified 312 early type star candidates from 5914 sources.

Early type stars follow a steep power law distribution, with a notable drop at ~10'' radius.

Detected significant early type stars outside 0.5 pc, supporting in-situ star formation.

Abstract

The goals of this work are to develop a new method to separate early and late type stellar components of a dense stellar cluster based on narrow band filters, to apply it to the central parsec of the GC, and to conduct a population analysis of this area. We use AO assisted observations obtained at the ESO VLT in the NIR H-band and 7 intermediate bands covering the NIR K-band. A comparison of the resulting SEDs with a blackbody of variable extinction then allows us to determine the presence and strength of a CO absorption feature to distinguish between early and late type stars. The new method is suitable to classify K giants (and later) as well as B2 main sequence (and earlier) stars which are brighter than 15.5 mag in the K band in the central parsec. Compared to previous spectroscopic investigations that are limited to 13-14 mag, this represents a major improvement in the depth of the observations as well as reducing the needed observation time. We classify 312 stars as early type candidates out of a sample of 5914 sources. The distribution of the early type stars can be fitted with a steep power law (beta(R>1'') = -1.49 +/- 0.12, alternatively with a broken power law, beta(R=1-10'') = -1.08 +/- 0.12, beta(R=10-20'') = -3.46 +/- 0.58, since we find a drop of the early type density at ~10''). We also detect early type candidates outside of 0.5 pc in significant numbers for the first time. The late type density function shows an inversion in the inner 6'', with a power law slope of beta(R<6'') = 0.17 +/- 0.09. The late type KLF has a power law slope of 0.30$\pm$0.01, closely resembling the KLF obtained for the bulge of the Milky Way. The early type KLF has a much flatter slope of 0.14 +/- 0.02. Our results agree best with an in-situ star formation scenario.