Resolving Stellar Atmospheres I: The H alpha line and comparisons to microlensing observations

TL;DR

This study compares LTE and NLTE stellar atmosphere models' H alpha spectral features with microlensing observations, highlighting the importance of NLTE modeling for accurate stellar parameter determination.

Contribution

It introduces a new shape parameter for H alpha line analysis and emphasizes the necessity of NLTE models in strong H alpha regimes.

Findings

NLTE models produce larger H alpha EW than LTE models.

Neither LTE nor NLTE models fit the line shape well, indicating unmodelled chromospheric emission.

A new shape parameter improves comparison between models and observations.

Abstract

We present work on H alpha spectral line characteristics in PHOENIX stellar model atmospheres and their comparison to microlensing observations. We examine in detail the H alpha equivalent width (EW) and the line shape characteristics for effective temperatures of 4500K< Teff < 5600K where H alpha is a strong spectral feature. We find that H alpha EW in models calculated under the assumption of local thermodynamic equilibrium (LTE) is up to 15% smaller than in models without this assumption, non-LTE models (NLTE) and that line shapes vary significantly for the two model types. A comparison with available high quality microlensing data, capable of tracing H alpha absorption across the face of one G5III giant, shows that the LTE model that fits the EW best is about 100K hotter than and the best-fitting NLTE model has a similar Teff as predicted by the spectral type analysis of the observed star but agree within the uncertainties of the observationally derived temperature. Neither LTE nor NLTE models fit the line shape well. We suspect unmodelled chromospheric emission. Line shape diagnostics suggest lower gravities than derived for the star and are unacceptable low in the case of the LTE models. We show that EW alone is insufficient for comparison to stellar model atmospheres, but combined with a new shape parameter we define is promising. In stellar parameter ranges where the H alpha line is strong, a NLTE approach of modeling stellar atmospheres is not only beneficial but mandatory.