# Gaia DR2 reveals a star formation burst in the disc 2-3 Gyr ago

**Authors:** R. Mor, A.C. Robin, F. Figueras, S. Roca-F\`abrega, X.Luri

arXiv: 1901.07564 · 2019-04-03

## TL;DR

Using Gaia DR2 data and advanced modeling, we identify a significant star formation burst in the Galactic disc 2-3 Gyr ago, revealing complex star formation history and IMF characteristics.

## Contribution

First non-parametric star formation history analysis for the Galactic thin disc using Gaia DR2 data within the Besancon Galaxy Model framework.

## Key findings

- Detected a star formation burst 2-3 Gyr ago in the thin disc.
- Observed a decreasing star formation rate from 9-10 Gyr to 6-7 Gyr ago.
- Estimated that about 50% of stellar mass was formed between 5 and 1 Gyr ago.

## Abstract

We use Gaia DR2 magnitudes, colours and parallaxes for stars with G<12 to explore a 15-dimensional space that includes simultaneously the initial mass function (IMF) and a non-parametric star formation history (SFH) for the Galactic disc. This inference is performed by combining the Besancon Galaxy Model fast approximate simulations (BGM FASt) and an approximate Bayesian computation algorithm. We find in Gaia DR2 data an imprint of a star formation burst 2-3 Gyr ago, in the Galactic thin disc domain, and a present star formation rate (SFR) of about 1 Msun. Our results show a decreasing trend of the SFR from 9-10 Gyr to 6-7 Gyr ago. This is consistent with the cosmological star formation quenching observed at redshifts z<1.8. This decreasing trend is followed by a SFR enhancement starting at about 5 Gyr ago and continuing until about 1 Gyr ago which is detected with high statistical significance by discarding the null hypothesis of an exponential SFH with a p-value=0.002. We estimate, from our best fit model, that about the 50% of the mass used to generate stars, along the thin disc life, was expended in the period from 5 to 1 Gyr ago. The timescale and the amount of stellar mass generated during the SFR enhancement event lead us to hypothesise that its origin, currently under investigation, is not intrinsic to the disc. Thus, an external perturbation is needed for its explanation. Additionally we find, for the thin disc, a slope of the IMF of $\alpha_3 \approx 2$ for masses M>1.53 Msun and $\alpha_2 \approx 1.3$ for the mass range between 0,5 and 1,53 Msun. This is the first time that we consider a non-parametric SFH for the thin disc in the Besancon Galaxy Model. This new step, together with the capabilities of the Gaia DR2 parallaxes to break degeneracies between different stellar populations, allow us to better constrain the SFH and the IMF.

## Full text

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## Figures

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## References

42 references — full list in the complete paper: https://tomesphere.com/paper/1901.07564/full.md

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Source: https://tomesphere.com/paper/1901.07564