The population of planetary nebulae and HII regions in M81. A study of radial metallicity gradients and chemical evolution

TL;DR

This study investigates the chemical abundances and radial metallicity gradients of planetary nebulae and HII regions in M81, revealing insights into its chemical evolution and comparing it with other galaxies like the Milky Way.

Contribution

First spectroscopic analysis of planetary nebulae in M81, providing new data on elemental abundances and metallicity gradients, and exploring their evolution over time.

Findings

M81 shows oxygen enrichment over the last ~10 Gyr.

The PN metallicity gradient is approximately -0.055 dex/kpc.

Evidence suggests a mild steepening of the metallicity gradient over time.

Abstract

We analyze the chemical abundances of planetary nebulae and HII regions in the M81 disk for insight on galactic evolution, and compare it with that of other galaxies, including the Milky Way. We acquired Hectospec/MMT spectra of 39 PNe and 20 HII regions, with 33 spectra viable for temperature and abundance analysis. Our PN observations represent the first PN spectra in M81 ever published, while several HII region spectra have been published before, although without a direct electron temperature determination. We determine elemental abundances of helium, nitrogen, oxygen, neon, sulfur, and argon in PNe and HII regions, and determine their averages and radial gradients. The average O/H ratio of PNe compared to that of the HII regions indicates a general oxygen enrichment in M81 in the last ~10 Gyr. The PN metallicity gradient in the disk of M81 is -0.055+-0.02 dex/kpc. Neon and sulfur in PNe have a radial distribution similar to that of oxygen, with similar gradient slopes. If we combine our HII sample with the one in the literature we find a possible mild evolution of the gradient slope, with results consistent with gradient steepening with time. Additional spectroscopy is needed to confirm this trend. There are no Type I PNe in our M81 sample, consistently with the observation of only the brightest bins of the PNLF, the galaxy metallicity, and the evolution of post-AGB shells. Both the young and the old populations of M81 disclose shallow but detectable negative radial metallicity gradient, which could be slightly steeper for the young population, thus not excluding a mild gradients steepening with the time since galaxy formation. During its evolution M81 has been producing oxygen; its total oxygen enrichment exceeds that of other nearby galaxies.