Absorption-line probes of the prevalence and properties of outflows in present-day star-forming galaxies

TL;DR

This study investigates how Na I absorption lines in star-forming galaxies reveal the presence and properties of galactic outflows, linking absorption features to galaxy characteristics like star formation and dust content.

Contribution

It provides a detailed analysis of Na I absorption components, distinguishing between disk and outflow features, and correlates these with galaxy physical properties using composite spectra.

Findings

Na D absorption lines are prevalent in galaxies with high extinction and star formation.

Outflow components are stronger near the galaxy rotation axis.

Disk absorption correlates with dust attenuation, suggesting dust shielding influences Na I survival.

Abstract

We analyze star forming galaxies drawn from SDSS DR7 to show how the interstellar medium (ISM) Na I 5890, 5896 (Na D) absorption lines depend on galaxy physical properties, and to look for evidence of galactic winds. We combine the spectra of galaxies with similar geometry/physical parameters to create composite spectra with signal-to-noise ~300. The stellar continuum is modeled using stellar population synthesis models, and the continuum-normalized spectrum is fit with two Na I absorption components. We find that: (1) ISM Na D absorption lines with equivalent widths EW > 0.8A are only prevalent in disk galaxies with specific properties -- large extinction (Av), high star formation rates (SFR), high star formation rate per unit area ($\Sigma_{\rm SFR}$), or high stellar mass (M*). (2) the ISM Na D absorption lines can be separated into two components: a quiescent disk-like component at the galaxy systemic velocity and an outflow component; (3) the disk-like component is much stronger in the edge-on systems, and the outflow component covers a wide angle but is stronger within 60deg of the disk rotation axis; (4) the EW and covering factor of the disk component correlate strongly with dust attenuation, highlighting the importance that dust shielding may play the survival of Na I. (5) The EW of the outflow component depends primarily on $\Sigma_{\rm SFR}$ and secondarily on Av; (6) the outflow velocity varies from ~120 to 160km/s but shows little hint of a correlation with galaxy physical properties over the modest dynamic range that our sample probes (1.2 dex in log$\Sigma_{\rm SFR}$ and 1 dex in log M*).