The IACOB project X. Large-scale quantitative spectroscopic analysis of Galactic luminous blue stars

TL;DR

This study provides the largest homogeneous spectroscopic analysis of Galactic luminous blue stars, revealing key stellar properties, rotational behaviors, and potential evolutionary clues, addressing discrepancies between models and observations.

Contribution

It offers a comprehensive, unbiased dataset of 527 Galactic luminous blue stars with derived physical parameters, enhancing understanding of their evolution and angular momentum transport.

Findings

Drop in star count at ~21 kK correlates with a scarcity of fast rotators.

Proposed angular momentum transport mechanism along the main sequence.

Less than 20% of stars show helium enrichment, possibly due to binary evolution.

Abstract

Blue supergiants (BSGs) are key objects for understanding the evolution of massive stars. However, discrepancies between theoretical predictions and empirical observations have opened up important questions yet to be answered. Studying statistically significant and unbiased samples of BSGs can help to improve the situation. We aim to perform a homogeneous and comprehensive quantitative spectroscopic analysis of a large sample of Galactic luminous blue stars (being the majority BSGs) from the IACOB spectroscopic database. We derive the projected rotational velocity ($v\sin i$) and macroturbulent broadening ($v_{\rm mac}$) using IACOB-BROAD. We used FASTWIND computations to derive effective temperatures ($T_{\rm eff}$), surface gravities, microturbulences ($\xi$), Si and He surface abundances, and the wind-strength parameter. We provide estimates of these quantities for the largest sample of Galactic luminous O9-B5 stars spectroscopically analyzed to date, with 527 targets. We find a drop in the relative number of stars at ~21 kK, coinciding with a scarcity of fast rotating stars below that temperature. We speculate that this feature might be roughly delineating the location of the Terminal-Age-Main-Sequence in the 15-85M$_\odot$ range. By investigating the main characteristics of the $v\sin i$ distribution as a function of $T_{\rm eff}$, we propose that an efficient mechanism transporting angular momentum from the stellar core to the surface might be operating along the main sequence. We find correlations between $\xi$, $v_{\rm mac}$ and the spectroscopic luminosity. We also find that no more than 20% of the stars in our sample have atmospheres clearly enriched in He, and suggest that the origin of this specific sub-sample might be in binary evolution. We do not find clear empirical evidence of an increase in the wind-strength over the wind bi-stability region towards lower temperatures.