Ionized gas in quiescent galaxies: Temperature measurement and constraint on the ionization source

TL;DR

This study measures gas temperatures in quiescent galaxies to determine the dominant ionization source of LIERs, finding strong evidence for shocks over other models through analysis of emission line ratios.

Contribution

It provides the first comprehensive temperature measurements in LIER regions, constraining the ionization mechanism to interstellar shocks using a large SDSS-IV MaNGA galaxy sample.

Findings

Temperatures are consistent with shock ionization models.

Shocks are supported as the main ionization source of LIERs.

Dust extinction estimates differ between Balmer decrement and forbidden line ratios.

Abstract

In non-star-forming, passively evolving galaxies, regions with emission lines dominated by low-ionization species are classified as Low-Ionization Emission Regions (LIERs). The ionization mechanism behind such regions has long been a mystery. Active Galactic Nuclei (AGNs), which were once believed to be the source, have been found not to be the dominant mechanism, especially in regions distant from the galaxy nuclei. The remaining candidates, photoionization by post-Asymtopic Giant Branch (pAGB) stars and interstellar shocks can only be distinguished with in-depth analysis. As the temperature predictions of these two models differ, temperature measurements can provide strong constraints on this puzzle. We selected a sample of 2795 quiescent red-sequence galaxies from the Sloan Digital Sky Survey IV (SDSS-IV) Mapping Nearby Galaxies at Apache Point Observatory (MaNGA) survey. We divided the sample spectra into three groups based on their [N II]/H$\alpha$ flux ratio and utilized stacking techniques to improve the signal-to-noise ratio of the observed spectra. We determined the temperature of [O III], [N II], [S II], and [O II] through their temperature-sensitive emission line ratios. Subsequently, we compared the measured temperatures with predictions from different models. The results demonstrate consistency with the interstellar shock model with preshock density n = 1 cm$^{-3}$ and solar metallicity, thus supporting shocks as the dominant ionization source of LIERs. Additionally, we also find that the interstellar dust extinction value measured through the Balmer decrement appears to be larger than that implied by the forbidden line ratios of low-ionization lines.