Using completely new ways of deducing the ages of so-called red giant stars from observational data, astronomers have created the first large-scale map that shows stellar ages in the Milky Way.

Determining the ages of nearly 100 000 red giant stars, at distances of up to 50 000 light-years from the galactic center, the astronomers, led by Melissa Ness and Marie Martig of the Max Planck Institute for Astronomy, were able to test key ideas about the growth of the Milky Way. Notably, the map confirms that our home galaxy has grown inside out: in the present epoch, most old stars can be found in the middle, more recently formed ones in the outskirts.

In the past decades, powerful astronomical surveys have provided astronomers with data about millions of astronomical objects, allowing for large-scale statistical analysis. But big data of this kind is only as good as the tools available for analysis.

Now, Melissa Ness and Marie Martig of the Max Planck Institute for Astronomy have added two powerful new tools to astronomy's arsenal: Using sample data from the APOGEE survey (part of the Sloan Digital Sky Survey) and NASA's Kepler Space Telescope, Ness and Martig devised two independent methods for determing the age of a red giant star from its spectrum (that is, from the properties of its light).

Using these methods, the astronomers were able to estimate the ages of nearly 100 000 stars that had been observed with the APOGEE survey. The result is an age map of the Milky Way, showing exactly which regions of our galaxy harbour young, old or middle-age stars. The map provides a representative cross section from the center of the Milky Way to the outskirts at a distance of 65 000 light-years from the galactic center.

With an age map of this kind, current models of how our home galaxy came into being and evolved can be put to the test.

For instance, such models predict that stellar disks, the dominant stellar component of galaxies like the Milky Way, should have formed from the inside out: so, one would expect to find the older stars closer to the galactic center, and the younger stars at the outside. The map confirms this distribution.

Also, at any given radius, the younger stars are typically found closer to the galactic plane than their older cousins. This is also confirmed by the age map of Ness and colleagues.

Techniques such as these promise much greater advantages once the data from future surveys such as APOGEE-2 or ESA's Gaia mission are in.

Eventually, it could help astronomers to reconstruct the entire star formation history of our galaxy: how many stars within our galaxy were formed at different times of galactic history, and in which regions, and how these stars have enriched our galaxy's raw material with the various elements they produce via nuclear fusion (thus enabling the production of heavier elements, of planets and, eventually, of living beings).

The results described here are published in Ness et al. The Cannon: A Data-driven Approach to Stellar Label Determination (published, Astrophysical Journal), Spectroscopic determination of masses (and implied ages) for red giants (Preprint, submitted to Astrophysical Journa), and Martig et al. Red giant masses and ages derived from carbon and nitrogen abundances (accepted for publication in MNRAS).

An in-depth description of the research and scientific background is available here.