The Importance of Galaxy-Wide Star Formation in Driving Winds at z~1

Abstract

In this work, we study winds for a representative sample of 86 star-forming galaxies (SFGs) at z~1 with M = 109.0-1011.5 M, by measuring the Mg II line profiles in deep Keck spectra. A total of 50 (58\%) are found to have winds. Unlike local starburst galaxies, the wind detection rate does not exhibit a threshold in star-formation rate (SFR) density ΣSFR at 0.1 Msun/yr/kpc2, but shows a gradual decline around this value. We find correlations between wind velocity vwind and SFR, ΣSFR, and stellar mass, as per previous studies. Intriguingly, the z~1 SFGs appear to follow the same vwind-SFR relation as local starbursts. A combined fit gives: log vwind = 0.16 log SFR + 2.4 (3-sigma significance). This unified relation spans over 4 dex in SFR and agrees with Illustris-TNG. No unified relation is found between vwind and stellar mass, sSFR, or ΣSFR. This suggests winds might be most closely associated with SFR. We examine whether winds in z~1 SFGs are driven by their most compact star-forming regions. To do so, we consider whether the relation between vwind and the ΣSFR measured from only these regions is stronger than that for the galaxy-wide ΣSFR. We do not find a stronger correlation, suggesting that winds are most related to ΣSFR of the entire galaxy. Collectively, these findings suggest a picture in which galaxy-wide star formation plays an important role in driving winds at z~1. Wind bubbles from all star-forming regions could combine momentum and help lift their entrained gas out of the galaxy.