Local Environments of Low-Redshift Supernovae

TL;DR

This study examines the local environments of different supernova types in nearby galaxies, revealing their association with star formation and stellar mass distributions using UV and IR observations.

Contribution

It provides a detailed analysis of the local star formation and mass environments of supernovae, highlighting differences among types and their relation to galaxy properties.

Findings

Core-collapse SNe are linked to star-forming regions.

Type Ia SNe are found in more quiescent regions.

SN distributions mirror IR light and star formation surface density.

Abstract

We characterize the local (2-kpc sized) environments of Type Ia, II, and Ib/c supernovae (SNe) that have recently occurred in nearby ($d\lesssim50$ Mpc) galaxies. Using ultraviolet (UV, from GALEX) and infrared (IR, from WISE) maps of 359 galaxies and a sample of 472 SNe, we measure the star formation rate surface density ($\Sigma_{\rm SFR}$) and stellar mass surface density ($\Sigma_\star$) in a 2-kpc beam centered on each SN site. We show that core-collapse SNe are preferentially located along the resolved galactic star-forming main sequence, whereas Type Ia SNe are extended to lower values of $\Sigma_{\rm SFR}$ at fixed $\Sigma_\star$, indicative of locations inside quiescent galaxies or quiescent regions of galaxies. We also test how well the radial distribution of each SN type matches the radial distributions of UV and IR light in each host galaxy. We find that, to first order, the distributions of all types of SNe mirror that of both near-IR light (3.4 and 4.5 microns, tracing the stellar mass distribution) and mid-IR light (12 and 22 microns, tracing emission from hot, small grains), and also resemble our best-estimate $\Sigma_{\rm SFR}$. All types of SNe appear more radially concentrated than the UV emission of their host galaxies. In more detail, the distributions of Type II SNe show small statistical differences from that of near-IR light. We attribute this overall structural uniformity to the fact that within any individual galaxy, $\Sigma_{\rm SFR}$ and $\Sigma_\star$ track one another well, with variations in $\Sigma_{\rm SFR}/\Sigma_\star$ most visible when comparing between galaxies.