The Origin of the Galaxy Mass-Metallicity Relation and Implications for Galactic Outflows

Abstract

(Abridged) Using cosmological hydrodynamic simulations in combination with analytic modeling, we show that the galaxy stellar mass-metallicity relation (MZR) provides strong constraints on galactic outflows across cosmic time. We compare three outflow models: No outflows, a "constant wind" (cw) model that emulates the popular Dekel & Silk (1986) scenario, and a ``momentum-driven wind" (vzw) model. We find that only the vzw scaling reproduces the observed z~2 MZR's slope, amplitude, and scatter. Comparing our fully three-dimensional simulations with a simple one-zone chemical evolution model, we find that the MZR can be understood in terms of three parameters: (1) The equilibrium metallicity Zeq=y*SFR/ACC (where y=true yield), reflecting the enrichment balance between star formation rate SFR and gas accretion rate ACC; (2) the dilution time td=Mg/ACC, representing the timescale for a galaxy to return to Zeq after a metallicity-perturbing interaction; and (3) the blowout mass Mblowout, which is the galaxy stellar mass above which winds can escape its halo. When outflows with mass loading factor MLF are present, galaxies below Mblowout obey Zeq = y/(1+MLF), while above Mblowout, Zeq->y. Our cw model has Mblowout ~ 1010 Msun, which yields a sharp upturn in the MZR above this scale and a flat MZR with large scatter below it, in strong disagreement with observations. Our vzw model reproduces the observed Zg M*0.3 because Zeq MLF-1 M*1/3 when MLF >> 1 (i.e. at low masses). The flattening of the MZR at M* > 1010.5 Msun observed by Tremonti et al. (2004) reflects the mass scale where MLF~1, rather than a characteristic wind speed. The tight observed MZR scatter is ensured when td<1 dynamical time, which is only satisified at all masses and epochs in our momentum-driven wind model.