Binaries drive high Type Ia supernova rates in dwarf galaxies

Abstract

The scaling of the specific Type Ia supernova (SN Ia) rate with host galaxy stellar mass NIa / M M-0.3 as measured in ASAS-SN and DES strongly suggests that the number of SNe Ia produced by a stellar population depends inversely on its metallicity. We estimate the strength of the required metallicity dependence by combining the average star formation histories (SFHs) of galaxies as a function of their stellar mass with the mass-metallicity relation (MZR) for galaxies and common parametrizations for the SN Ia delay-time distribution. The differences in SFHs can account for only 30% of the increase in the specific SN Ia rate between stellar masses of M = 1010 and 107.2 M. We find that an additional metallicity dependence of approximately -0.5 is required to explain the observed scaling. This scaling matches the metallicity dependence of the close binary fraction observed in APOGEE, suggesting that the enhanced SN Ia rate in low-mass galaxies can be explained by a combination of their more extended SFHs and a higher binary fraction due to their lower metallicities. Due to the shape of the MZR, only galaxies below M ≈ 3×109 M are significantly affected by the metallicity-dependent SN Ia rates. The NIa / M M-0.3 scaling becomes shallower with increasing redshift, dropping by factor of 2 at 107.2 M between z = 0 and 1 with our -0.5 scaling. With metallicity-independent rates, this decrease is a factor of 3. We discuss the implications of metallicity-dependent SN Ia rates for one-zone models of galactic chemical evolution.