Electron-beam interaction with emission-line clouds in blazars
Abstract
Context: An electron-positron beam escaping from the magnetospheric vacuum gap of an accreting black hole interacts with recombination-line photons from surrounding gas clouds. Inverse-Compton scattering and subsequent pair production initiate unsaturated electromagnetic cascades exhibiting a characteristic spectral energy distribution. Aims: By modelling the interactions of beam electrons (positrons) with hydrogen and helium recombination-line photons, we seek to describe the spectral signature of beam-driven cascades in the broad emission-line region of blazar jets. Methods: Employing coupled kinetic equations for electrons (positrons) and photons including an escape term, we numerically obtain their steady-state distributions, and the escaping photon spectrum. Results: We find that cascade emission resulting from beam interactions can produce a narrow spectral feature at TeV energies. Indications of such an intermittent feature, which defies an explanation in the standard shock-in-jet scenario, have been found at confidence level at an energy of 3 TeV in the spectrum of the blazar Mrk 501. Conclusions: The energetic requirements for explaining the intermittent 3 TeV bump with the beam-interaction model are plausible: Gap discharges that lead to multi-TeV beam electrons (positrons) carrying 0.1 % of the Blandford-Znajek luminosity, which interact with recombination-line photons from gas clouds that reprocess 1 % of the similar accretion luminosity are required.
Cite
@article{arxiv.2012.05215,
title = {Electron-beam interaction with emission-line clouds in blazars},
author = {Christoph Wendel and Josefa Becerra González and David Paneque and Karl Mannheim},
journal= {arXiv preprint arXiv:2012.05215},
year = {2021}
}
Comments
Accepted for publication in Astronomy and Astrophysics on 07.12.2020. Article comprises 15 pages including the appendices and six figures. Edition with corrected typos and clean grammar