The Absolute Magnitudes of Type Ia Supernovae in the Ultraviolet

TL;DR

This study analyzes the ultraviolet absolute magnitudes and light-curve behaviors of nearby Type Ia supernovae, revealing significant spectral variability and potential for improved distance measurements using UV data.

Contribution

It provides new insights into UV spectral variability and correlations with optical decay rates, enhancing understanding of SNe Ia as standard candles.

Findings

Large scatter in mid-UV absolute magnitudes suggests metallicity effects.

Near-UV magnitudes correlate with optical decay rates, aiding distance estimation.

Significant spectral variability below 2600 Å impacts UV-based supernova analysis.

Abstract

We examine the absolute magnitudes and light-curve shapes of 14 nearby(redshift z = 0.004--0.027) Type Ia supernovae (SNe~Ia) observed in the ultraviolet (UV) with the Swift Ultraviolet/Optical Telescope. Colors and absolute magnitudes are calculated using both a standard Milky Way (MW) extinction law and one for the Large Magellanic Cloud that has been modified by circumstellar scattering. We find very different behavior in the near-UV filters (uvw1_rc covering ~2600-3300 A after removing optical light, and u ~3000--4000 A) compared to a mid-UV filter (uvm2 ~2000-2400 A). The uvw1_rc-b colors show a scatter of ~0.3 mag while uvm2-b scatters by nearly 0.9 mag. Similarly, while the scatter in colors between neighboring filters is small in the optical and somewhat larger in the near-UV, the large scatter in the uvm2-uvw1 colors implies significantly larger spectral variability below 2600 A. We find that in the near-UV the absolute magnitudes at peak brightness of normal SNe Ia in our sample are correlated with the optical decay rate with a scatter of 0.4 mag, comparable to that found for the optical in our sample. However, in the mid-UV the scatter is larger, ~1 mag, possibly indicating differences in metallicity. We find no strong correlation between either the UV light-curve shapes or the UV colors and the UV absolute magnitudes. With larger samples, the UV luminosity might be useful as an additional constraint to help determine distance, extinction, and metallicity in order to improve the utility of SNe Ia as standardized candles.