No double detonations but core carbon ignitions in high-resolution, grid-based simulations of binary white dwarf mergers

TL;DR

This study uses high-resolution 3D simulations to explore white dwarf mergers, revealing a novel core detonation mechanism in C/O mergers that could explain certain Type Ia supernovae, without supporting double-detonation scenarios.

Contribution

The paper introduces a new core detonation mechanism in massive C/O white dwarf mergers, challenging previous double-detonation models and providing detailed simulation evidence.

Findings

Identified a novel core detonation mechanism in C/O mergers.

Explosion energy and nickel mass are consistent with bright Type Ia supernovae.

Double-detonation scenarios are not supported for systems with helium secondary.

Abstract

We study the violent phase of the merger of massive binary white dwarf systems. Our aim is to characterize the conditions for explosive burning to occur, and identify a possible explosion mechanism of Type Ia supernovae. The primary components of our model systems are carbon-oxygen (C/O) white dwarfs, while the secondaries are made either of C/O or of pure helium. We account for tidal effects in the initial conditions in a self-consistent way, and consider initially well-separated systems with slow inspiral rates. We study the merger evolution using an adaptive mesh refinement, reactive, Eulerian code in three dimensions, assuming symmetry across the orbital plane. We use a co-rotating reference frame to minimize the effects of numerical diffusion, and solve for self-gravity using a multi-grid approach. We find a novel detonation mechanism in C/O mergers with massive primaries. Here the detonation occurs in the primary's core and relies on the combined action of tidal heating, accretion heating, and self-heating due to nuclear burning. The exploding structure is compositionally stratified, with a reverse shock formed at the surface of the dense ejecta. The existence of such a shock has not been reported elsewhere. The explosion energy ($1.6\times 10^{51}$ erg) and $^{56}$Ni mass (0.86 M$_\odot$) are consistent with a SN Ia at the bright end of the luminosity distribution, with an approximated decline rate of $\Delta m_{15}(B)\approx 0.99$. Our study does not support double-detonation scenarios in the case of a system with a 0.6 M$_\odot$ helium secondary and a 0.9 M$_\odot$ primary. Although the accreted helium detonates, it fails to ignite carbon at the base of the boundary layer or in the primary's core.