SN 2016coi (ASASSN-16fp): An Energetic H-stripped Core-collapse Supernova from a Massive Stellar Progenitor with Large Mass Loss
Hurley, K.; Challis, P.; Stanek, K. Z.; Dong, Subo; Brimacombe, J.; Benetti, S.; Chornock, R.; Shappee, B. J.; Stritzinger, M. D.; Migliori, G.; Bersier, D.; Marchant, P.; Palmer, D. M.; Elias-Rosa, N.; Mattila, S.; Tomasella, L.; Guidorzi, C.; Prieto, J. L.; Terreran, G.; Gall, C.; Milisavljevic, D.; Margutti, R.; Coppejans, D. L.; Pastorello, A.; Chen, Ping; DeMarchi, L.; Harmanen, J.; Kirshner, R.; Caprioli, D.
United States, United Kingdom, Australia, China, Italy, Chile, Denmark, Spain, Finland
Abstract
We present comprehensive observations and analysis of the energetic H-stripped SN 2016coi (a.k.a. ASASSN-16fp), spanning the γ-ray through optical and radio wavelengths, acquired within the first hours to ∼420 days post explosion. Our observational campaign confirms the identification of He in the supernova (SN) ejecta, which we interpret to be caused by a larger mixing of Ni into the outer ejecta layers. By modeling the broad bolometric light curve, we derive a large ejecta-mass-to-kinetic-energy ratio (M ej ∼ 4-7 M ⊙, E k ∼ (7-8) × 1051 erg). The small [Ca II] λλ7291,7324 to [O I] λλ6300,6364 ratio (∼0.2) observed in our late-time optical spectra is suggestive of a large progenitor core mass at the time of collapse. We find that SN 2016coi is a luminous source of X-rays (L X > 1039 erg s-1 in the first ∼100 days post explosion) and radio emission (L 8.5 GHz ∼ 7 × 1027 erg s-1 Hz-1 at peak). These values are in line with those of relativistic SNe (2009bb, 2012ap). However, for SN 2016coi, we infer substantial pre-explosion progenitor mass loss with a rate \dot{M} ∼ (1-2) × {10}-4 {M}⊙ {yr}}-1 and a sub-relativistic shock velocity v sh ∼ 0.15c, which is in stark contrast with relativistic SNe and similar to normal SNe. Finally, we find no evidence for a SN-associated shock breakout γ-ray pulse with energy E γ > 2 × 1046 erg. While we cannot exclude the presence of a companion in a binary system, taken together, our findings are consistent with a massive single-star progenitor that experienced large mass loss in the years leading up to core collapse, but was unable to achieve complete stripping of its outer layers before explosion.