Evolution of Gas Flows along the Starburst to Post-Starburst to Quiescent Galaxy Sequence

TL;DR

This study tracks how neutral galactic winds evolve across starburst, post-starburst, and quiescent galaxies, revealing diminishing outflows and the influence of AGN activity and galaxy orientation on wind properties.

Contribution

It provides the first large-scale analysis of how galactic winds change during galaxy evolution, highlighting the decline of outflows and the role of AGN and disk orientation.

Findings

Outflow fraction decreases from 76% to 65% to 34%.

Mean velocity shifts from outflowing to inflowing as galaxies age.

AGN activity correlates with the fastest outflows in post-starburst galaxies.

Abstract

We measure velocity offsets in the NaI $\lambda\lambda5890, 5896$ (Na D) interstellar medium absorption lines to track how neutral galactic winds change as their host galaxies evolve. Our sample of $\sim$80,000 SDSS spectra at $0.010 < z < 0.325$ includes starburst, post-starburst, and quiescent galaxies, forming an evolutionary sequence of declining star formation rate (SFR). We detect bulk flows across this sequence, mostly at higher host stellar masses($log(M_{\star}/M_{\odot})>10$). Along this sequence, the fraction of outflows decreases ($76\pm2\%$ to $65\pm4\%$ to a 3$\sigma$ upper limit of $34\%$), and the mean velocity offset changes from outflowing to inflowing ($-84.6\pm5.9$ to $-71.6\pm11.4$ to $76.6\pm2.3\,km\,s^{-1}$). Even within the post-starburst sample, wind speed decreases with time elapsed since the starburst ended. These results reveal that outflows diminish as galaxies age. For post-starbursts, there is evidence for an AGN contribution, especially to the speediest outflows: 1) SFR declines faster in time than outflow velocity, a decoupling arguing against massive stellar feedback; 2) of the few outflows strong enough to escape the interstellar medium (9/105), three of the four hosts with measured emission lines are Seyfert galaxies. For disky starburst galaxies, however, the trends suggest flows out of the stellar disk plane (with outflow 1/2-opening angle $> 45$ degree) instead of from the nucleus: the wind velocity decreases as the disk becomes more edge-on, and the outflow fraction, constant at $\sim$90$\%$ for disk inclinations $i<45$ degree, steadily decreases from $\sim$90$%$ to 20$\%$ for $i>45$ degree.