Electron-capture Supernova Candidates from Light Curves: Implications for Their Progenitors and Explosion Properties

Abstract

Core-collapse supernovae are explosions of massive stars. While most massive stars end as iron-core-collapse supernovae, less massive stars are expected to explode as electron-capture supernovae (ECSNe), defining the low-mass boundary of core-collapse supernovae. ECSNe were proposed 40 years ago, and first-principles simulations predict their successful explosions with low energies of 1050~erg. Nevertheless, only one convincing candidate, SN~2018zd, has been proposed other than SN~1054, the progenitor of the Crab Nebula. We search for ECSN candidates among Type~II SNe from the literature and a public Zwicky Transient Facility sample, using a color-based diagnostic, selecting ten candidates with blue colors at the middle of the plateau. We classify three as gold, for which a spectrum around the middle of the plateau disfavors strong circumstellar-medium interaction that would make the SN bluer, and seven as silver without such spectra. Comparing the observed multicolor light curves with radiation-hydrodynamical models, we infer the explosion energies, (0.4-1.7)×1050~erg for the gold candidates and (0.4-2.7)×1050~erg including the silver candidates, consistent with first-principles predictions and the mass-loss rates, 3×10-3 - 3 × 10-2~M~ yr-1 for the gold candidates, which remain similar when the silver candidates are included, higher than those expected for the early super-asymptotic-giant-branch phase. The ECSN occurrence ratios among SNe~II are inferred as 3.0+10.6-2.9 and 15.7+17.3-12.7~\% from the gold and silver candidates, respectively, which we interpret as lower and upper limits. To robustly identify ECSNe and refine this ratio, spectroscopic follow-ups of ECSN candidates around the middle of the plateau are essential.