The Iron Yield of Core-collapse Supernovae

We present a systematic analysis of 191 stripped-envelope supernovae (SE SNe), aimed at computing their 56 Ni masses from the luminosity in their radioactive tails ( M Ni tail ) and/or in their maximum light, and the mean 56 Ni and iron yields of SE SNe and core-collapse SNe. Our sample consists of SNe IIb, Ib, and Ic from the literature and from the Zwicky Transient Facility Bright Transient Survey. To calculate luminosities from optical photometry, we compute bolometric corrections using 49 SE SNe with optical and near-IR photometry, and develop corrections to account for the unobserved UV and IR flux. We find that the equation of Khatami & Kasen for radioactive 56 Ni-powered transients with a single free parameter does not fit the observed peak time–luminosity relation of SE SNe. Instead, we find a correlation between M Ni tail , peak time, peak luminosity, and decline rate, which allows for measuring individual 56 Ni masses to a precision of 14%. Applying this method to the whole sample, we find, for SNe IIb, Ib, and Ic, mean 56 Ni masses of 0.066 ± 0.006, 0.082 ± 0.009, and 0.132 ± 0.011 M ⊙ , respectively. After accounting for their relative rates, for SE SNe as a whole, we compute mean 56 Ni and iron yields of 0.090 ± 0.005 and 0.097 ± 0.007 M ⊙ , respectively. Combining these results with the recent Type II SN mean 56 Ni mass derived by Rodríguez et al., core-collapse SNe, as a whole, have mean 56 Ni and iron yields of 0.055 ± 0.006 and 0.058 ± 0.007 M ⊙ , respectively. We also find that radioactive 56 Ni-powered models typically underestimate the peak luminosity of SE SNe by 60%–70%, suggesting the presence of an additional power source contributing to the luminosity at peak.