Sulphur abundances in star-forming regions from optical emission lines: A new approach based on photoionization models consistent with the direct method

TL;DR

This paper introduces a new photoionization model-based method to accurately determine sulphur abundances in star-forming regions using optical emission lines, aligning with the direct method without extra assumptions.

Contribution

A novel approach using adapted photoionization models to estimate sulphur abundance directly from optical lines, even without auroral lines, improving accuracy over previous methods.

Findings

No significant deviation of S/O from solar in most of the metallicity range.

Possible sulphur enhancement at high metallicity levels.

Oxygen depletion onto dust grains may explain observed abundance patterns.

Abstract

The derivation of sulphur chemical abundances in the gas-phase of star-forming galaxies is explored in this work, using the emission lines produced in these regions in the optical part of the spectrum and by means of photoionization models. We adapted the code HII-CHI-mistry to account for these abundances by implementing additional grids of models that assume a variable sulphur-to-oxygen abundance ratio, beyond the commonly assumed solar value. The addition of these models, and their use in a new iteration of the code allows us to use sulphur lines to precisely estimate the sulphur abundance, even in the absence of auroral lines. This approach aligns with the results from the direct method, and no additional assumptions about the ionization correction factor are needed, as the models directly predict the total sulphur abundance. We applied this new methodology to a large sample of star-forming regions from the MaNGA survey, and we explored the variation of the S/O ratio as a function of metallicity, making corrections for the significant contribution from diffuse ionized gas, which particularly affects the [SII] emission. Our results indicate no significant deviations from the solar S/O value in the range 8.0 < 12+log(O/H) < 8.7, where the bulk of the MaNGA sample stays, but also with possible enhancements of sulphur at the high metallicity regime. This may be linked to the depletion of oxygen in the gas-phase due to its incorporation onto dust grains, as it remains when other metallicity indicators independent of this depletion, as S/H itself, are used instead.