# Globular clusters with Gaia

**Authors:** E. Pancino (INAF-OAA, ASDC), M. Bellazzini (INAF-OABO), G.Giuffrida, (INAF-ROMA, ASDC), and S. Marinoni (INAF-ROMA, ASDC)

arXiv: 1701.03003 · 2017-01-12

## TL;DR

This paper assesses Gaia's capabilities for studying globular clusters, modeling crowding errors, and predicting the quality of astrometric, photometric, and kinematic data for various cluster types and distances.

## Contribution

It provides a detailed simulation-based analysis of Gaia's expected performance on globular clusters, considering crowding effects and instrument limitations.

## Key findings

- 103-104 stars with minimal crowding effects will be measurable in most clusters.
- Systemic proper motions and parallaxes will be accurate to 1% up to 15 kpc.
- Internal kinematics and cluster masses can be determined with high precision.

## Abstract

The treatment of crowded fields in Gaia data will only be a reality in a few years from now. In particular, for globular clusters, only the end-of-mission data (public in 2022-2023) will have the necessary full crowding treatment and will reach sufficient quality for the faintest stars. As a consequence, the work on the deblending and decontamination pipelines is still ongoing. We describe the present status of the pipelines for different Gaia instruments, and we model the end-of-mission crowding errors on the basis of available information. We then apply the nominal post-launch Gaia performances, appropriately worsened by the estimated crowding errors, to a set of 18 simulated globular clusters with different concentration, distance, and field contamination. We conclude that there will be 103-104 stars with astrometric performances virtually untouched by crowding (contaminated by <1 mmag) in the majority of clusters. The most limiting factor will be field crowding, not cluster crowding: the most contaminated clusters will only contain 10-100 clean stars. We also conclude that: (i) the systemic proper motions and parallaxes will be determined to 1% or better up to 15 kpc, and the nearby clusters will have radial velocities to a few km/s ; (ii) internal kinematics will be of unprecendented quality, cluster masses will be determined to 10% up to 15 kpc and beyond, and it will be possible to identify differences of a few km/s or less in the kinematics (if any) of cluster sub-populations up to 10 kpc and beyond; (iii) the brightest stars (V<17 mag) will have space-quality, wide-field photometry (mmag errors), and all Gaia photometry will have 1-3% errors on the absolute photometric calibration.

## Full text

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## Figures

46 figures with captions in the complete paper: https://tomesphere.com/paper/1701.03003/full.md

## References

62 references — full list in the complete paper: https://tomesphere.com/paper/1701.03003/full.md

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Source: https://tomesphere.com/paper/1701.03003