Constraints on star-formation driven galaxy winds from the mass-metallicity relation at z=0

TL;DR

This study constrains galaxy wind efficiencies at z=0 by linking the mass-metallicity relation with gas fractions, demonstrating that strong, mass-dependent outflows are necessary to explain observed metallicities and gas content.

Contribution

It introduces a chemical evolution model incorporating gas fractions and outflows, providing new constraints on the scaling of star-formation driven winds with galaxy mass.

Findings

Efficient outflows are required to reproduce the mass-metallicity relation.

The metal expulsion efficiency scales steeply with galaxy virial velocity.

Momentum- or energy-driven models predict different scaling relations than observed.

Abstract

We extend a chemical evolution model relating galaxy stellar mass and gas-phase oxygen abundance (the mass-metallicity relation) to explicitly consider the mass-dependence of galaxy gas fractions and outflows. Using empirically derived scalings of galaxy mass with halo virial velocity in conjunction with the most recent observations of z~0 total galaxy cold gas fractions and the mass-metallicity relation, we place stringent global constraints on the magnitude and scaling of the efficiency with which star forming galaxies expel metals. We demonstrate that under the assumptions that metal accretion is negligible and the stellar initial mass function does not vary, efficient outflows are required to reproduce the mass-metallicity relation; without winds, gas-to-stellar mass ratios >~ 0.3 dex higher than observed are needed. Moreover, z=0 gas fractions are low enough that while they have some effect on the magnitude of outflows required, the slope of the gas fraction--stellar mass relation does not strongly affect our conclusions on how the wind efficiencies must scale with galaxy mass. Despite systematic uncertainties in the normalization and slope of the mass-metallicity relation, we show that the metal expulsion efficiency zetaw=(Zw/Zg)etaw (where Zw is the wind metallicitiy and Zg is the interstellar medium metallicity) must be both high and scale steeply with mass. Specifically, we show that zetaw >> 1 and zetaw proportional to vvir^-3 or steeper. In contrast, momentum- or energy-driven outflow models suggest that etaw should scale as vvir^-1 or vvir^-2, respectively, implying that the Zw-Mstar relation should be shallower than the Zg-Mstar relation. [abridged]