Revealing the binary origin of Type Ic superluminous supernovae through nebular hydrogen emission

TL;DR

This paper suggests that nebular hydrogen emission in a Type Ic superluminous supernova originates from matter stripped from a massive companion star during the supernova explosion, indicating a close binary system.

Contribution

It provides evidence linking nebular hydrogen emission to binary interaction in Type Ic superluminous supernovae, proposing a new interpretation for their progenitor systems.

Findings

Stripped mass of 0.1-0.9 solar masses explains H-alpha luminosity.

Progenitor likely in a close binary system with a companion over 20 solar masses.

Early brightening may be due to collision with a close companion.

Abstract

We propose that nebular H-alpha emission as detected in the Type Ic superluminous supernova iPTF13ehe stems from matter which is stripped from a companion star when the supernova ejecta collide with it. The temporal evolution, the line broadening, and the overall blueshift of the emission are consistent with this interpretation. We scale the nebular H-alpha luminosity predicted for Type Ia supernovae in single-degenerate systems to derive the stripped mass required to explain the H-alpha luminosity of iPTF13ehe. We find a stripped mass of 0.1 - 0.9 solar masses, assuming that the supernova luminosity is powered by radioactivity or magnetar spin down. Because a central heating source is required to excite the H-alpha emission, an interaction-powered model is not favored for iPTF13ehe if the H-alpha emission is from stripped matter. We derive a companion mass of more than 20 solar masses and a binary separation of less than about 20 companion radii based on the stripping efficiency during the collision, indicating that the supernova progenitor and the companion formed a massive close binary system. If Type Ic superluminous supernovae generally occur in massive close binary systems, the early brightening observed previously in several Type Ic superluminous supernovae may also be due to the collision with a close companion. Observations of nebular hydrogen emission in future Type Ic superluminous supernovae will enable us to test this interpretation.