Electromagnetic signatures of white dwarf collisions in AGN discs

TL;DR

This paper explores the electromagnetic signatures of white dwarf collisions in AGN discs, predicting high-energy transients, their characteristics, and implications for AGN metallicity and changing-look phenomena.

Contribution

It introduces a novel model for white dwarf collision-induced transients in AGN discs, detailing their energy conversion, observational signatures, and impact on AGN properties.

Findings

Transient luminosity follows a t^{-2.8} decay.

Time-scale varies from hours to weeks depending on SMBH mass.

Fallback ejecta enhances AGN metallicity and element synthesis.

Abstract

In the inner region of the disc of an active galactic nucleus (AGN), the collision of two white dwarfs (WDs) through Jacobi capture might be inevitable, leading to a Type Ia supernova (SN Ia) explosion. This transient event, influenced by the disc gas and the gravity of the supermassive black hole (SMBH), exhibits distinct characteristics compared to normal SNe Ia. The energy of the explosion is mainly stored in the ejecta in the form of kinetic energy. Typically, the ejecta is not effectively decelerated by the AGN disc and rushes rapidly out of the AGN disc. However, under the influence of the SMBH, most of the ejecta falls back toward the AGN disc. As the fallback ejecta becomes more dispersed, it interacts with the disc gas, converting its kinetic energy into thermal energy. This results in a high-energy transient characterized by a rapid initial rise followed by a decay with $L\propto t^{-2.8}$. The time-scale of the transient ranges from hours to weeks, depending on the mass of the SMBH. This process generates high-energy radiation spanning from hard X-rays to the soft $\gamma$ range. Additionally, the subsequent damage to the disc may result in changing-look AGNs. Moreover, the falling back of SNe Ia ejecta onto the AGN disc significantly increases the metallicity of the AGN and can even generate heavy elements within the AGN discs.