Systematic Investigation of Very Early-Phase Spectra of Type Ia Supernovae

TL;DR

This study models very early spectra of Type Ia supernovae to constrain their explosion mechanisms and progenitor systems, revealing diversity in ejecta properties and suggesting two possible progenitor channels.

Contribution

It provides the first detailed modeling of early-phase spectra of SNe Ia to link spectral features with explosion models and progenitor scenarios.

Findings

Normal-velocity SNe Ia have photospheric velocities around 15000 km/s.

Outer ejecta velocities range between 20000 and 25000 km/s.

Two distinct groups are suggested: high-density, carbon-poor and low-density, carbon-rich SNe.

Abstract

It has been widely accepted that Type Ia supernovae (SNe Ia) are thermonuclear explosions of a CO white dwarf. However, the natures of the progenitor system(s) and explosion mechanism(s) are still unclarified. Thanks to the recent development of transient observations, they are now frequently discovered shortly after the explosion, followed by rapid spectroscopic observations. In this study, by modeling very early-phase spectra of SNe Ia, we try to constrain the explosion models of SNe Ia. By using the Monte Carlo radiation transfer code, TARDIS, we estimate the properties of their outermost ejecta. We find that the photospheric velocity of normal-velocity supernovae (NV SNe) in the first week is $\sim$15000 km s$^{-1}$. The outer velocity, to which the carbon burning extends, spans the range between $\sim$20000 and 25000 km s$^{-1}$. The ejecta density of NV SNe also shows a large diversity. For high-velocity supernovae (HV SNe) and 1999aa-like SNe, the photospheric velocity is higher, $\sim$20000 km s$^{-1}$. They are different in the photospheric density, with HV SNe having higher density than 1999aa-like SNe. For all these types, we show that the outermost composition is closely related to the outermost ejecta density; the carbon burning layer and the unburnt carbon layer are found in the higher-density and lower-density objects, respectively. This finding suggests that there might be two sequences, the high-density and carbon-poor group (HV SNe and some NV SNe) and the low-density and carbon-rich group (1999aa-like and other NV SNe), which may be associated with different progenitor channels.