A faint type of supernova from a white dwarf with a helium-rich companion

TL;DR

This paper reports the discovery of a faint, helium-rich supernova originating from an old stellar system, likely involving a white dwarf and a helium-rich companion, representing a new type of stellar explosion.

Contribution

It introduces a new class of supernova from a white dwarf with a helium-rich companion, distinct from known core-collapse and type Ia supernovae.

Findings

The supernova is located in a region with no recent star formation.

Ejected mass is approximately 0.3 solar masses.

Ejecta are dominated by helium-burning products and contain high calcium and radioactive 44Ti.

Abstract

Supernovae (SNe) are thought to arise from two different physical processes. The cores of massive, short-lived stars undergo gravitational core collapse and typically eject a few solar masses during their explosion. These are thought to appear as as type Ib/c and II SNe, and are associated with young stellar populations. A type Ia SN is thought to arise from the thermonuclear detonation of a white dwarf star composed mainly of carbon and oxygen, whose mass approaches the Chandrasekhar limit. Such SNe are observed in both young and old stellar environments. Here we report our discovery of the faint type Ib SN 2005E in the halo of the nearby isolated galaxy, NGC 1032. The lack of any trace of recent star formation near the SN location (Fig. 1), and the very low derived ejected mass (~0.3 M_sun), argue strongly against a core-collapse origin for this event. Spectroscopic observations and the derived nucleosynthetic output show that the SN ejecta have high velocities and are dominated by helium-burning products, indicating that SN 2005E was neither a subluminous nor a regular SN Ia (Fig. 2). We have therefore found a new type of stellar explosion, arising from a low-mass, old stellar system, likely involving a binary with a primary white dwarf and a helium-rich secondary. The SN ejecta contain more calcium than observed in any known type of SN and likely additional large amounts of radioactive 44Ti. Such SNe may thus help resolve fundamental physical puzzles, extending from the composition of the primitive solar system and that of the oldest stars, to the Galactic production of positrons.