The Nickel Mass Distribution of Stripped-Envelope Supernovae: Implications for Additional Power Sources

Abstract

We perform a systematic study of the 56Ni mass (M Ni) of 27 stripped envelope supernovae (SESNe) by modeling their light-curve tails, highlighting that use of ``Arnett's rule'' overestimates M Ni for SESN by a factor of 2. Recently, Khatami2019 presented a new model relating the peak time (t p) and luminosity (L p) of a radioactive-powered SN to its M Ni that addresses several limitations of Arnett-like models, but depends on a dimensionless parameter, β. Using observed t p, L p, and tail-measured M Ni values for 27 SESN, we observationally calibrate β for the first time. Despite scatter, we demonstrate that the model of Khatami2019 with empirically-calibrated β values provides significantly improved measurements of M Ni when only photospheric data is available. However, these observationally-constrained β values are systematically lower than those inferred from numerical simulations, primarily because the observed sample has significantly higher (0.2-0.4 dex) L p for a given M Ni. While effects due to composition, mixing, and asymmetry can increase L p current models cannot explain the systematically low β values. However, the discrepancy can be alleviated if 7--50\% of L p for the observed sample originates from sources other than 56Ni. Either shock cooling or magnetar spin-down could provide the requisite luminosity. Finally, we find that even with our improved measurements, the M Ni values of SESN are still a factor of 3 larger than those of hydrogen-rich Type II SN, indicating that these supernovae are inherently different in terms of their progenitor initial mass distributions or explosion mechanisms.