HII Region Metallicity Distribution in the Milky Way Disk

TL;DR

This study measures the metallicity distribution in the Milky Way's disk using radio observations of HII regions, revealing a radial gradient and azimuthal inhomogeneities that suggest metals are not uniformly mixed.

Contribution

It provides the first detailed measurement of the Galactic metallicity gradient using radio recombination lines and highlights azimuthal variations in metal distribution.

Findings

Galactic O/H gradient of approximately -0.038 to -0.045 dex/kpc.

No evidence of discontinuities in the metallicity gradient.

Significant azimuthal inhomogeneities in metal distribution.

Abstract

The distribution of metals in the Galaxy provides important information about galaxy formation and evolution. HII regions are the most luminous objects in the Milky Way at mid-infrared to radio wavelengths and can be seen across the entire Galactic disk. We used the NRAO Green Bank Telescope (GBT) to measure radio recombination line and continuum emission in 81 Galactic HII regions. We calculated LTE electron temperatures using these data. In thermal equilibrium metal abundances are expected to set the nebular electron temperature with high abundances producing low temperatures. Our HII region distribution covers a large range of Galactocentric radius (5 to 22 kpc) and samples the Galactic azimuth range 330 degree to 60 degree. Using our highest quality data (72 objects) we derived an O/H Galactocentric radial gradient of -0.0383 +/- 0.0074 dex/kpc. Combining these data with a similar survey made with the NRAO 140 Foot telescope we get a radial gradient of -0.0446 +/- 0.0049 dex/kpc for this larger sample of 133 nebulae. The data are well fit by a linear model and no discontinuities are detected. Dividing our sample into three Galactic azimuth regions produced significantly different radial gradients that range from -0.03 to -0.07 dex/kpc. These inhomogeneities suggest that metals are not well mixed at a given radius. We stress the importance of homogeneous samples to reduce the confusion of comparing data sets with different systematics. Galactic chemical evolution models typically derive chemical evolution along only the radial dimension with time. Future models should consider azimuthal evolution as well.