Collisions of white dwarfs as a new progenitor channel for type Ia supernovae

TL;DR

This study explores a novel progenitor scenario for type Ia supernovae involving white dwarf collisions, demonstrating that such events can produce observable supernovae with characteristics similar to normal type Ia explosions.

Contribution

The paper introduces and models a collision-based progenitor channel for type Ia supernovae, expanding the understanding beyond traditional Chandrasekhar mass ignition scenarios.

Findings

White dwarf collisions can naturally trigger thermonuclear explosions producing Ni.

Synthetic light curves and spectra resemble those of normal type Ia supernovae.

Event rates may contribute up to 1% of all type Ia supernovae, especially in dense stellar environments.

Abstract

We present the results of a systematic numerical study of an alternative progenitor scenario to produce type Ia supernova explosions, which is not restricted to the ignition of a CO white dwarf near the Chandrasekhar mass. In this scenario, a shock-triggered thermonuclear explosion ensues from the collision of two white dwarfs. Consistent modeling of the gas dynamics together with nuclear reactions using both a smoothed particle and a grid-based hydrodynamics code are performed to study the viability of this alternative progenitor channel. We find that shock-triggered ignition and the synthesis of Ni are in fact a natural outcome for moderately massive white dwarf pairs colliding close to head-on. We use a multi-dimensional radiative transfer code to calculate the emergent broadband light curves and spectral time-series of these events. The synthetic spectra and lightcurves compare well with those of normal type Ia supernovae over a similar B-band decline rate and are broadly consistent with the Phillips relation, although a mild dependence on viewing angle is observed due to the asymmetry of the ejected debris. While event rates within galactic centers and globular clusters are found to be much too low to explain the bulk of the type Ia supernovae population, they may be frequent enough to make as much as a one percent contribution to the overall rate. Although these rate estimates are still subject to substantial uncertainties, they do suggest that dense stellar systems should provide upcoming supernova surveys with hundreds of such collision-induced thermonuclear explosions per year.