Thermonuclear explosion of a massive hybrid HeCO white-dwarf triggered by a He-detonation on a companion

TL;DR

This study uses detailed 3D simulations to explore how a helium detonation on a hybrid HeCO white dwarf can trigger a supernova explosion, revealing a new explosion mechanism with observable signatures.

Contribution

It presents the first self-consistent 3D simulation showing a helium shell detonation on a hybrid HeCO WD can lead to its destruction and produce a faint transient, expanding understanding of supernova progenitors.

Findings

Helium detonation occurs but does not trigger carbon detonation in the CO WD.

The helium shell detonation causes the destruction of the hybrid HeCO WD.

Potential observable transient with high-velocity ejected companion.

Abstract

Normal type Ia supernovae (SNe) are thought to arise from the thermonuclear explosion of massive ($>0.8$ M$_\odot$) carbon-oxygen white dwarfs (WDs), although the exact mechanism is debated. In some models helium accretion onto a carbon-oxygen (CO) WD from a companion was suggested to dynamically trigger a detonation of the accreted helium shell. The helium detonation then produces a shock that after converging on itself close to the core of the CO-WD, triggers a secondary carbon detonation and gives rise to an energetic explosion. However, most studies of such scenarios have been done in one or two dimensions, and/or did not consider self-consistent models for the accretion and the He-donor. Here we make use of detailed 3D simulation to study the interaction of a He-rich hybrid $0.69\,\mathrm{M_\odot}$ HeCO WD with a more massive $0.8\,\mathrm{M_\odot}$ CO~WD. We find that accretion from the hybrid WD onto the CO~WD gives rise to a helium detonation. However, the helium detonation does not trigger a carbon detonation in the CO~WD. Instead, the helium detonation burns through the accretion stream to also burn the helium shell of the donor hybrid HeCO-WD. The detonation of its massive helium shell then compresses its CO core, and triggers its detonation and full destruction. The explosion gives rise to a faint, likely highly reddened transient, potentially observable by the Vera Rubin survey, and the high-velocity ($\sim 1000\,\mathrm{km s^{-1}}$) ejection of the heated surviving CO~WD companion. Pending on uncertainties in stellar evolution we estimate the rate of such transient to be up to $\sim10\%$ of the rate of type Ia SNe.