UV-extended E-MILES stellar population models: young components in massive early-type galaxies

TL;DR

This paper introduces UV-extended E-MILES stellar population models that cover a broad spectral range, improving resolution and parameter coverage, and used to analyze the stellar components of early-type galaxies.

Contribution

The study presents new UV-extended stellar population models with enhanced resolution and broader age/metallicity coverage, enabling detailed analysis of young stellar components in massive early-type galaxies.

Findings

Models fit well to Milky Way and LMC clusters.

UV analysis reveals young stellar components in ETGs.

Age estimates from UV and optical are consistent.

Abstract

We present UV-extended E-MILES stellar population synthesis models covering the spectral range 1680-50000A at moderately high resolution. We employ the NGSL space-based stellar library to compute spectra of single-age, single-metallicity stellar populations in the wavelength range from 1680 to 3540A. These models represent a significant improvement in resolution and age/metallicity coverage over previous studies based on earlier space-based libraries. These model spectra were joined with those we computed in the visible using MILES, and other empirical libraries for redder wavelengths. The models span the metallicity range -1.79<[M/H]<+0.26 and ages above 30 Myr, for a suite of IMF types with varying slopes. We focus on the behaviour of colours, spectra and line-strength indices in the UV range as a function of relevant stellar population parameters. Whereas some indices strengthen with increasing age and metallicity, as most metallicity indicators in the visible, other indices peak around 3 Gyr for metal-rich stellar populations, such as Mg at 2800A. Our models provide reasonably good fits to the integrated colours and most line-strengths of the stellar clusters of the Milky-Way and LMC. Our full-spectrum fits in the UV range for a representative set of ETGs of varying mass yield age and metallicity estimates in very good agreement with those obtained in the optical range. The comparison of UV colours and line-strengths of massive ETGs with our models reveals the presence of young stellar components, with ages in the range 0.1-0.5 Gyr and mass fractions 0.1-0.5%, on the top of an old stellar population.