On the maximum luminosities of normal stripped-envelope supernovae -- brighter than explosion models allow

TL;DR

This study analyzes a large sample of Type Ibc supernovae from ZTF, revealing many are brighter than current explosion models predict, indicating a need to revise theoretical understanding of supernova luminosities.

Contribution

It provides the first extensive observational evidence that normal Type Ibc supernovae can exceed the maximum luminosity predicted by existing models.

Findings

129 supernovae analyzed, with 36% brighter than models predict

94 supernovae with well-measured luminosities, some exceeding theoretical limits

Indicates a discrepancy between observed supernova brightness and explosion model predictions

Abstract

Stripped-envelope supernovae (SE SNe) of Type Ib and Type Ic are thought to result from explosions of massive stars having lost their outer envelopes. The favoured explosion mechanism is by core-collapse, with the shock later revived by neutrino heating. However, there is an upper limit to the amount of radioactive Nickel-56 that such models can accomplish. Recent literature point to a tension between the maximum luminosity from such simulations and observations. We use a well characterized sample of SE SNe from the Zwicky Transient Facility (ZTF) Bright Transient Survey (BTS) to collect a sample of spectroscopically classified normal Type Ibc SNe for which we use the ZTF light curves to determine the maximum luminosity. We cull the sample further based on data quality, light-curve shape, distance and colors. The methodology of the sample construction from this BTS sample can be used for many other future investigations. In total we use 129 Type Ib or Type Ic BTS SNe with an initial rough luminosity distribution peaked at Mr = -17.61 +- 0.72, and where 36% are apparently brighter than the theoretically predicted maximum brightness of Mr = -17.8. When we further cull this sample to ensure that the SNe are normal Type Ibc with good LC data within the Hubble flow, the sample of 94 objects has Mr = -17.64 +- 0.54. A main uncertainty in absolute magnitude determinations for SNe is the host galaxy extinction correction, but the reddened objects only get more luminous after corrections. If we simply exclude objects with red, unusual or uncertain colors, we are left with 14 objects at M = -17.90 +- 0.73, whereof a handful are most certainly brighter than the suggested theoretical limit. The main result of this study is thus that normal SNe Ibc do indeed reach luminosities above $10^{42.6}$ erg/s, apparently in conflict with existing explosion models.