Type Ib/Ic supernovae: effect of nickel mixing on the early-time color evolution and implications for the progenitors

TL;DR

This study uses radiation hydrodynamics simulations to explore how nickel mixing influences the early color evolution of Type Ib and Ic supernovae, revealing differences in progenitors and mixing strength.

Contribution

It introduces a detailed analysis of nickel mixing effects on supernova color evolution, linking observational signatures to progenitor composition and mixing levels.

Findings

Weak nickel mixing causes three-phase color evolution.

Strong nickel mixing eliminates the blueward phase.

SNe Ib and Ic show signatures of differing nickel mixing levels.

Abstract

We investigate the effect of mixing of radioactive nickel ($^{56}$Ni) on the early-time color evolution of Type Ib and Ic supernovae (SNe Ib/Ic) using multi-group radiation hydrodynamics simulations. We consider both helium-rich and helium-poor progenitors. Mixing of $^{56}$Ni is parameterized using a Gaussian distribution function. We find that the early-time color evolution with a weak $^{56}$Ni mixing is characterized by three different phases: initial rapid reddening, blueward evolution due to the delayed effect of $^{56}$Ni heating, and redward evolution thereafter until the transition to the nebular phase. With a strong $^{56}$Ni mixing, the second phase disappears. We compare our models with the early-time color evolution of several SNe Ib/Ic (SN1999ex, SN 2008D, SN 2009jf, iPTF13bvn, SN 1994I, SN 2007gr, SN 2013ge, and 2017ein) and find signatures of relatively weak and strong $^{56}$Ni mixing for SNe Ib and SNe Ic, respectively. This suggests that SNe Ib progenitors are distinct from SN Ic progenitors in terms of helium content and that $^{56}$Ni mixing is generally stronger in the carbon-oxygen core and weaker in the helium-rich envelope. We conclude that the early-time color evolution is a powerful probe of $^{56}$Ni mixing in SNe Ib/Ic.