Chemical enrichment in LINERs from MaNGA. II. Characterizing the shape of their radial metallicity gradients

TL;DR

This study analyzes the radial metallicity gradients in LINER-like galaxies using MaNGA data, revealing complex profiles likely influenced by AGN feedback, and highlights the diversity of chemical enrichment patterns across galaxy disks.

Contribution

First analysis of chemical abundance gradients in LINER galaxies using integral field spectroscopy, introducing a piecewise fitting method to characterize complex radial profiles.

Findings

Most galaxies show departures from single linear gradients in metallicity and N/O ratios.

No correlation between gradient shapes and galaxy properties like mass or velocity dispersion.

AGN feedback may influence the observed chemical abundance profiles.

Abstract

Chemical abundance radial gradients provide key information on how the processes that affect chemical enrichment of the gas-phase interstellar medium (ISM) act at different galaxy scales. Whereas in the last decades there has been an increase in the number of galaxies studied with integral field spectroscopy, there is still not a clear picture on a subsequent characterization of the chemical abundance radial gradients in galaxies hosting Active Galactic Nuclei (AGNs). This lack of analysis is even more accentuated in the case of low-ionization nuclear emission-line regions (LINERs). For the first time, we analyze the chemical abundance radial gradients in a sample of LINER-like galaxies, whose nuclear emission has been previously (Paper I) discussed. We use a sample of 97 galaxies from the Mapping Nearby Galaxies at Apache Point Observatory (MaNGA), whose nuclear regions show LINER-like emission. We use the open-source code HII-CHI-Mistry to estimate the chemical abundance ratios 12+log(O/H) and log(N/O) in the HII regions across the disks in our sample, as well as in the nuclear parts where the LINER-like activity dominates. To fit the radial profiles we use a piecewise methodology which uses a non-fixed number of breaks to find the best fit for the data. We obtain that majority of our sample of galaxies exhibits departures from the single linear gradient both in 12+log(O/H) and log(N/O) (as expected from the inside-out scenario). We investigate whether these departures are driven by galaxy properties (stellar mass, neutral gas mass, stellar velocity dispersion), finding not correlation at all. We also report that in most cases there is no correlation between the shape of the 12+log(O/H) and log(N/O) radial profiles. We propose a model in which AGN (feed)back, acting at different scales depending on the galaxy and its evolutionary stage, might be responsible for these departures.