# The Milky Way like galaxy NGC 6384 and its nuclear star cluster at high   NIR spatial resolution using LBT/ARGOS commissioning data

**Authors:** Iskren Y. Georgiev, Nadine Neumayer, Wolfgang Gaessler, Sebastian, Rabien, Lorenzo Busoni, Marco Bonaglia, Julian Ziegleder, Gilles Orban de, Xivry, Diethard Peter, Martin Kulas, Jose Borelli, Gustavo Rahmer, Michael, Lefebvre, Holger Baumgardt

arXiv: 1901.06350 · 2019-01-30

## TL;DR

This study demonstrates high-resolution near-infrared imaging of NGC 6384 using LBT/ARGOS AO, revealing detailed structures of its nuclear star cluster and central regions, and deriving their properties through combined imaging and photometry.

## Contribution

It showcases the capability of ground-layer adaptive optics to analyze galaxy nuclei at distances previously only accessible from space, providing detailed structural and stellar population insights.

## Key findings

- Nuclear star cluster has an effective radius of ~10 pc.
- Identified surrounding structures with effective radii of ~100 pc and ~400 pc.
- Derived stellar population properties including age, metallicity, and mass ratios.

## Abstract

We analyse high spatial resolution near infra-red (NIR) imaging of NGC6384, a Milky Way like galaxy, using ARGOS commissioning data at the Large Binocular Telescope (LBT). ARGOS provides a stable PSF$_{\rm FWHM}\!=\!0.2"\!-\!0.3"$ AO correction of the ground layer across the LUCI2 NIR camera $4'\!\times4'$ field by using six laser guide stars (three per telescope) and a natural guide star for tip-tilt sensing and guiding. Enabled by this high spatial resolution we analyse the structure of the nuclear star cluster (NSC) and the central kiloparsec of NGC6384. We find via 2D modelling that the NSC ($r_{\rm eff}\!\simeq\!10$pc) is surrounded by a small ($r_{\rm eff}\!\simeq\!100$pc) and a larger Sersi\'c ($r_{\rm eff}\!\simeq\!400$pc), all embedded within the NGC\,6384 large-scale boxy/X-shaped bulge and disk. This proof-of-concept study shows that with the high spatial resolution achieved by ground-layer AO we can push such analysis to distances previously only accessible from space. SED-fitting to the NIR and optical HST photometry allowed to leverage the age-metallicity-extinction degeneracies and derive the effective NSC properties of an young to old population mass ratio of $8\%$ with ${\cal M}_{\rm\star,old}\!\simeq\!3.5\times10^7M_\odot$, Age$_{\rm old,\ young}\!=\!10.9\pm1.3$Gyr and 226\,Myr $\pm62\%$, metallicity [M/H]$=\!-0.11\pm0.16$ and $0.33\pm39\%$dex, and $E(B\!-\!V)\!=\!0.63$ and 1.44mag.

## Full text

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## Figures

51 figures with captions in the complete paper: https://tomesphere.com/paper/1901.06350/full.md

## References

99 references — full list in the complete paper: https://tomesphere.com/paper/1901.06350/full.md

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Source: https://tomesphere.com/paper/1901.06350