Dissecting Galaxies with Quantitative Spectroscopy of the Brightest Stars in the Universe

TL;DR

This paper discusses how quantitative spectroscopy of the brightest stars, blue supergiants, can accurately determine galaxy properties and distances, surpassing traditional methods and extending reach to tens of megaparsecs.

Contribution

It introduces the Flux-weighted Gravity - Luminosity Relationship (FGLR) as a new method for precise extragalactic distance measurement using blue supergiants.

Findings

Spectroscopic analysis provides detailed chemical abundances and gradients.

The FGLR method offers an accurate alternative for distance determination.

Current 10m telescopes can study galaxies up to 10 Mpc away.

Abstract

Measuring distances to galaxies, determining their chemical composition, investigating the nature of their stellar populations and the absorbing properties of their interstellar medium are fundamental activities in modern extragalactic astronomy helping to understand the evolution of galaxies and the expanding universe. The optically brightest stars in the universe, blue supergiants of spectral A and B, are unique tools for these purposes. With absolute visual magnitudes up to M_V = -9.5 they are the ideal to obtain accurate quantitative information about galaxies through the powerful modern methods of quantitative stellar spectroscopy. The spectral analyis of individual blue supergiant targets provides invaluable information about chemical abundances and abundance gradients, which is more comprehensive than the one obtained from HII regions, as it includes additional atomic species, and which is also more accurate, since it avoids the systematic uncertainties inherent in the strong line studies usually applied to the HII regions of spiral galaxies beyond the Local Group. Simultaneously, the spectral analysis yields stellar parameters and interstellar extinction for each individual supergiant target, which provides an alternative very accurate way to determine extragalactic distances through a newly developed method, called the Flux-weighted Gravity - Luminosity Relationship (FGLR). With the present generation of 10m-class telescopes these spectroscopic studies can reach out to distances of 10 Mpc. The new generation of 30m-class will allow to extend this work out to 30 Mpc, a substantial volume of the local universe.