Exploring metallicity-dependent rates of Type Ia supernovae and their impact on galaxy formation

TL;DR

This study uses cosmological simulations to examine how metallicity-dependent Type Ia supernova rates influence galaxy evolution, showing that such models align better with observations without disrupting galaxy properties.

Contribution

It introduces and tests metallicity-dependent Ia supernova rate models within galaxy formation simulations, demonstrating improved consistency with observational data.

Findings

Metallicity-dependent Ia rates improve agreement with observed stellar metallicities.

Such models do not significantly alter galaxy sizes or morphologies.

Enhanced Ia rates in low-metallicity environments better match supernova observations.

Abstract

Type Ia supernovae play a critical role in stellar feedback and elemental enrichment in galaxies. Recent transient surveys like the All-Sky Automated Survey for Supernova (ASAS-SN) and the Dark Energy Survey (DES) find that the specific Ia rate at z ~ 0 may be ~ 15-50 times higher in lower-mass galaxies than at Milky Way-mass. Independently, Milky Way observations show that the close-binary fraction of solar-type stars is higher at lower metallicity. Motivated by these observations, we use the FIRE-2 cosmological zoom-in simulations to explore the impact of varying Ia rate models, including metallicity dependence, on galaxies across a range of stellar masses: 10^7 Msun - 10^{11} Msun. First, we benchmark our simulated star-formation histories (SFHs) against observations. We show that assumed SFHs and stellar mass functions play a major role in determining the degree of tension between observations and metallicity-independent Ia rate models, and potentially cause ASAS-SN and DES observations to be much more consistent with each other than might naively appear. Models in which the Ia rate increases with decreasing metallicity (as ~ Z^{-0.5} to Z^{-1}) provide significantly better agreement with observations. Encouragingly, these increases in Ia rate (> 10 times in low-mass galaxies) do not significantly impact galaxy stellar masses and morphologies: effective radii, axis ratios, and v/sigma remain largely unaffected except for our most extreme rate models. We explore implications for both [Fe/H] and [alpha/Fe] enrichment: metallicity-dependent Ia rate models can improve agreement with observed stellar mass-metallicity relations in low-mass galaxies. Our results demonstrate that a wide range of metallicity-dependent Ia models are viable for galaxy formation and motivate future work in this area.