Nuclear $\gamma$-ray emission from very hot accretion flows

TL;DR

This paper investigates nuclear gamma-ray emissions from hot accretion flows around black holes, revealing significant gamma-ray line luminosities and neutron production, with implications for high-energy astrophysics.

Contribution

It introduces a detailed nuclear reaction network in accretion flows, quantifies gamma-ray line emissivity, and explores neutron evaporation in ADAF models, advancing understanding of high-energy processes near black holes.

Findings

Gamma-ray line luminosity can reach up to 10^{-3} of accretion luminosity.

Up to 15% of accreting mass can evaporate as neutrons.

High-energy gamma-ray production efficiency can be as high as 1%.

Abstract

Optically thin accretion plasmas can reach ion temperatures $T_{\rm i} \geq 10^{10}$K and thus trigger nuclear reactions. Using a large nuclear interactions network, we studied the radial evolution of the chemical composition of the accretion flow toward the black hole and computed the emissivity in nuclear $\gamma$-ray lines. In the advection dominated accretion flow (ADAF) regime, CNO and heavier nuclei are destroyed before reaching the last stable orbit. The overall luminosity in the de-excitation lines for a solar composition of plasma can be as high as few times $10^{-5}$ the accretion luminosity ($\dot{M}c^2$) and can be increased for heavier compositions up to $10^{-3}$. The efficiency of transformation of the kinetic energy of the outflow into high energy ($\geq 100$~MeV) $\gamma$-rays through the production and decay of $\pi^0$-mesons can be higher, up to $10^{-2}$ of the accretion luminosity. We show that in the ADAF model up to 15 percent of the mass of accretion matter can `evaporate' in the form of neutrons.