Smoothed Particle Hydrodynamics simulations of white dwarf collisions and close encounters

TL;DR

This paper presents detailed smoothed particle hydrodynamics simulations of white dwarf collisions, analyzing outcomes, gravitational wave signatures, and fallback luminosities to improve understanding of these astrophysical events.

Contribution

It introduces an advanced SPH simulation approach with detailed physics and explores various collision scenarios and their observational signatures.

Findings

Fallback luminosities near 10^48 erg/s

Distinct gravitational waveforms for different collision types

Survival conditions of binary white dwarfs after close encounters

Abstract

The collision of two white dwarfs is a quite frequent event in dense stellar systems, like globular clusters and galactic nuclei. In this paper we present the results of a set of simulations of the close encounters and collisions of two white dwarfs. We use an up- to-date smoothed particle hydrodynamics code that incorporates very detailed input physics and an improved treatment of the artificial viscosity. Our simulations have been done using a large number of particles (~ 4 \times 10^5) and covering a wide range of velocities and initial distances of the colliding white dwarfs. We discuss in detail when the initial eccentric binary white dwarf survives the closest approach, when a lateral collision in which several mass transfer episodes occur is the outcome of the newly formed binary system, and which range of input parameters leads to a direct collision, in which only one mass transfer episode occurs. We also discuss the characteristics of the final configuration and we assess the possible observational signatures of the merger, such as the associated gravitational waveforms and the fallback luminosities. We find that the overall evolution of the system and the main characteristics of the final object agree with those found in previous studies. We also find that the fallback luminosities are close to 10^48 erg/s. Finally, we find as well that in the case of lateral and direct collisions the gravitational waveforms are characterized by large-amplitude peaks which are followed by a ring-down phase, while in the case in which the binary white dwarf survives the closest approach, the gravitational pattern shows a distinctive behavior, typical of eccentric systems.