Neutrino and pair creation in reconnection-powered coronae of accreting black holes

Abstract

A ubiquitous feature of accreting black hole systems is their hard X-ray emission which is thought to be produced through Comptonization of soft photons by electrons and positrons in the vicinity of the black hole, in a region with optical depth of order unity. The origin and composition of this Comptonizing region, known as the corona, is a matter open for debate. In this paper we investigate the role of relativistic protons accelerated in black-hole magnetospheric current sheets for the pair enrichment and neutrino emission of AGN coronae. Our model has two free parameters, namely the proton plasma magnetization σ p, which controls the peak energy of the neutrino spectrum, and the Eddington ratio λ X, Edd (defined as the ratio between X-ray luminosity L X and Eddington luminosity L Edd), which controls the amount of energy transferred to secondary particles. For sources with λ X, Edd λ Edd, crit (where λ Edd, crit 10-1 for σ p=105 or 10-2 for σ p=107), proton-photon interactions and γ γ annihilation produce enough secondary pairs to achieve Thomson optical depths τ T 0.1-10. In the opposite case of λ X, Edd λ Edd, crit, the coronal pairs cannot originate only from hadronic interactions. Additionally, we find that the neutrino luminosity scales as L2 X/L Edd for λ X, Edd λ Edd, crit, while it is proportional to L X for higher λ X, Edd values. We apply our model to four Seyfert galaxies, including NGC 1068, and discuss our results in light of recent IceCube observations.

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