Seeing the Outer Edge of the Infant Type Ia Supernova 2024epr in the Optical and Near Infrared

TL;DR

This paper presents early optical and NIR observations of SN 2024epr, revealing high-velocity features and unusual colors that challenge existing models, emphasizing the importance of earliest data for understanding Type Ia supernovae.

Contribution

It provides the earliest optical and NIR spectra of SN 2024epr, revealing high-velocity features and unusual early colors that constrain supernova explosion models.

Findings

High-velocity Ca and Si features near 0.1c observed early

SN 2024epr shows stronger peak Ca absorption than typical SNe Ia

Early-time colors are red, indicating unique explosion properties

Abstract

We present optical-to-near-infrared (NIR) photometry and spectroscopy of the Type Ia supernova (SN Ia) 2024epr, including NIR spectra observed within two days of first light. The early-time optical spectra show strong, high-velocity Ca and Si features near rarely-observed velocities at $\sim$0.1$c$, and the NIR spectra show a C I "knee." Despite early-time, high-velocity features, SN 2024epr evolves into a normal SN Ia, albeit with stronger peak-light Ca absorption than other SNe Ia with the same light curve shape. Although we infer a normal decline rate, $\Delta m_{15}(B)=1.09\pm0.12$ mag, from the light-curve rise, SN 2024epr is a Branch "cool" object and has red early-time colors ($g-r\approx0.15$ mag at $-10$ days). The high velocities point to a density enhancement in the outer layers of the explosion, predicted by some models, but thick-shell He-detonation models do not match the smoothly rising light curve or apparent lack of He in our early-time NIR spectra. No current models (e.g., delayed detonation or thin He shell double detonation) appear to reproduce all observed properties, particularly the unusual early-time colors. Such constraints are only possible for SN 2024epr from the earliest optical and NIR observations, highlighting their importance for constraining SN Ia models. Finally, we identify several literature SNe Ia with intermediate mass elements at $\sim$30\,000 km s$^{-1}$ within days after the explosion that evolve into otherwise normal SNe Ia at peak light, suggesting the early-time spectra of SNe Ia may hide a broad diversity of observational characteristics.