The bolometric light curves and physical parameters of stripped-envelope supernovae

TL;DR

This study constructs and analyzes bolometric light curves of 85 stripped-envelope supernovae to derive their physical parameters, revealing differences in luminosity, nickel synthesis, and light curve evolution among subtypes.

Contribution

It provides a consistent analysis of supernova light curves and introduces new insights into subtype luminosities, nickel production, and the importance of host-galaxy extinction.

Findings

Broad-lined SNe Ic-BL are the most luminous subtype.

SNe Ic-BL synthesize about twice the nickel of other types.

SNe Ic-BL and Ic have faster rise times from half-peak to peak.

Abstract

The optical and optical/near-infrared pseudo-bolometric light curves of 85 stripped-envelope supernovae (SNe) are constructed using a consistent method and a standard cosmology. The light curves are analysed to derive temporal characteristics and peak luminosity $L_{\mathrm{p}}$, enabling the construction of a luminosity function. Subsequently, the mass of $^{56}$Ni synthesised in the explosion, along with the ratio of ejecta mass to ejecta kinetic energy, are found. Analysis shows that host-galaxy extinction is an important factor in accurately determining luminosity values as it is significantly greater than Galactic extinction in most cases. It is found that broad-lined SNe~Ic (SNe~Ic-BL) and gamma-ray burst SNe are the most luminous subtypes with a combined median $L_{\mathrm{p}}$, in erg s$^{-1}$, of log($L_{\mathrm{p}})=43.00$ compared to $42.51$ for SNe Ic, $42.50$ for SNe~Ib, and $42.36$ for SNe~IIb. It is also found that SNe~Ic-BL synthesise approximately twice the amount of $^{56}$Ni compared with SNe~Ic, Ib, and IIb, with median $M_{\mathrm{Ni}} = 0.34$, 0.16, 0.14, and 0.11 M$_{\odot}$, respectively. SNe~Ic-BL, and to a lesser extent SNe~Ic, typically rise from $L_{\mathrm{p}}/2$ to $L_{\mathrm{p}}$ more quickly than SNe~Ib/IIb; consequently, their light curves are not as broad.