Prelude to a double degenerate merger: the onset of mass transfer and its impact on gravitational waves and surface detonations

TL;DR

This study systematically investigates the onset of mass transfer in double degenerate binaries, revealing long-lived transfer phases, their gravitational wave signatures, and conditions for surface detonations, with implications for understanding Type Ia supernovae.

Contribution

It provides the first comprehensive numerical analysis showing that unstable mass transfer can persist for many orbits, challenging previous disruption assumptions and improving modeling accuracy.

Findings

Long-lived mass transfer phases lasting dozens of orbits.

Gravitational wave signals from these binaries are significant for high-frequency detectors.

Conditions for surface detonations are identified during the mass transfer process.

Abstract

We present the results of a systematic numerical study of the onset of mass transfer in double degenerate binary systems and its impact on the subsequent evolution. All investigated systems belong to the regime of direct impact, unstable mass transfer. In all of the investigated cases, even those considered unstable by conventional stability analysis, we find a long-lived mass transfer phase continuing for as many as several dozen orbital periods. This settles a recent debate sparked by a discrepancy between earlier SPH calculations that showed disruptions after a few orbital periods and newer grid-based studies in which mass transfer continued for tens of orbits. As we show that these binaries can survive at small separation for hundreds of orbital periods, their associated gravitational wave signal should be included when calculating the gravitational wave foreground (although expected to below LISA's sensitivity at these high frequencies). We also show that the inclusion of the entropy increase associated with shock-heating of the accreted material reduces the number of orbits a binary survives given the same initial conditions, although the effect is not as pronounced when using the appropriate initial conditions. The use of accurate initial conditions and a correct treatment of shock heating allows for a reliable time evolution of the temperature, density, and angular momentum, which are important when considering thermonuclear events that may occur during the mass transfer phase and/or after merger. Our treatment allows us to accurately identify when surface detonations may occur in the lead-up to the merger, as well as the properties of final merger products.