On the origin of optical and IR emission lines in star forming galaxies

TL;DR

This study combines photoionization modeling with stellar population synthesis to analyze emission lines in star-forming galaxies, revealing that shocks and weak AGN outflows may influence galaxy classification more than previously thought.

Contribution

It introduces a new approach integrating MIR and FIR diagnostic diagrams with updated models, challenging the assumption that post-AGB stars are the main ionizers in certain galaxies.

Findings

Most MIR-optically classified HII galaxies are at very low metallicity.

Shock models can reproduce the MIR diagnostic diagram features.

A new demarcation line for retired galaxies in the BPT diagram is proposed.

Abstract

Combining the {\sc Cloudy} photoionization code with updated stellar population synthesis results, we simultaneously model the MIR $\neiii/\neii$ vs. $\oiv/\neiii$, the MIR-FIR $\neiii/\neii$ vs. $\oiv/\oiii$ and the classical BPT diagnostic diagrams. We focus on the properties of optically classified \hii\,galaxies that lie in the normal star forming zone in the MIR diagnostic diagram. We find that a small fraction of our models lie in this zone, but most of them correspond to the lowest explored metallicity, \zstar\,=\,0.0002, at age $\sim1$ Gyr. This value of \zstar\,is, by far, lower than the values derived for these galaxies from optical emission lines, suggesting that the far-UV emission produced by post-AGB stars (a.k.a. HOLMES, hot low-mass evolved stars) is NOT the source of ionization. Instead, shock models can easily reproduce this part of the MIR diagram. We suggest that it is likely that some of these galaxies have been misclassified and that in them, shocks, produced by a weak AGN-outflow, could be an important source of ionizaton. Using a subset of our models, we derive a new demarcation line for the maximal contribution of retired galaxies in the BPT diagram. This demarcation line allows for a larger contamination from the neighbouring AGN-dominated region. Considering the importance of disentangling the different ionising mechanisms in weak or deeply obscured systems, new observational efforts to classify galaxies both in the optical and IR are required to better constrain this kind of models and understand their evolutionary paths.