Supernova Light Curves Powered by Fallback Accretion

TL;DR

This paper explores how fallback accretion onto compact remnants in supernovae can power diverse and luminous light curves, potentially explaining peculiar supernova observations.

Contribution

It introduces spherically symmetric hydrodynamical models to quantify fallback accretion effects on supernova light curves, highlighting conditions that lead to super-luminous and peculiar supernovae.

Findings

Fallback accretion can significantly enhance supernova brightness.

Accretion-driven outflows can re-energize supernova ejecta.

Different fallback scenarios produce diverse supernova light curves.

Abstract

Some fraction of the material ejected in a core collapse supernova explosion may remain bound to the compact remnant, and eventually turn around and fall back. We show that the late time (> days) power associated with the accretion of this "fallback" material may significantly affect the optical light curve, in some cases producing super-luminous or otherwise peculiar supernovae. We use spherically symmetric hydrodynamical models to estimate the accretion rate at late times for a range of progenitor masses and radii and explosion energies. The accretion rate onto the proto-neutron star or black hole decreases as Mdot ~ t^-5/3 at late times, but its normalization can be significantly enhanced at low explosion energies, in very massive stars, or if a strong reverse shock wave forms at the helium/hydrogen interface in the progenitor. If the resulting super-Eddington accretion drives an outflow which thermalizes in the outgoing ejecta, the supernova debris will be re-energized at a time when photons can diffuse out efficiently. The resulting light curves are different and more diverse than previous fallback supernova models which ignored the input of accretion power and produced short-lived, dim transients. The possible outcomes when fallback accretion power is significant include super-luminous (> 10^44 ergs / s) Type II events of both short and long durations, as well as luminous Type I events from compact stars that may have experienced significant mass loss. Accretion power may unbind the remaining infalling material, causing a sudden decrease in the brightness of some long duration Type II events. This scenario may be relevant for explaining some of the recently discovered classes of peculiar and rare supernovae.