Abstract
The Universe is filled with a diffuse background of MeV gamma-rays and PeV neutrinos, whose origins are unknown. Here, we propose a scenario that can account for both backgrounds simultaneously. Low-luminosity active galactic nuclei have hot accretion flows where thermal electrons naturally emit soft gamma rays via Comptonization of their synchrotron photons. Protons there can be accelerated via turbulence or reconnection, producing high-energy neutrinos via hadronic interactions. We demonstrate that our model can reproduce the gamma-ray and neutrino data. Combined with a contribution by hot coronae in luminous active galactic nuclei, these accretion flows can explain the keV – MeV photon and TeV – PeV neutrino backgrounds. This scenario can account for the MeV background without non-thermal electrons, suggesting a higher transition energy from the thermal to nonthermal Universe than expected. Our model is consistent with X-ray data of nearby objects, and testable by future MeV gamma-ray and high-energy neutrino detectors.
Highlights
The Universe is filled with a diffuse background of MeV gamma-rays and PeV neutrinos, whose origins are unknown
We describe the properties of the thermal plasma in radiatively inefficient accretion flows (RIAFs)
M_is the normalized mass accretion rate, B is the magnetic field, τT is the Thomson optical depth, Θe is the normalized electron temperature, αIC is the spectral index of Comptonized photons, εγγ is the cutoff energy of photons by γγ interactions, LHα is the Hα luminosity, PCR=Pth is the ratio of CR pressure to thermal one
Summary
The Universe is filled with a diffuse background of MeV gamma-rays and PeV neutrinos, whose origins are unknown. Low-luminosity active galactic nuclei have hot accretion flows where thermal electrons naturally emit soft gamma rays via Comptonization of their synchrotron photons. Combined with a contribution by hot coronae in luminous active galactic nuclei, these accretion flows can explain the keV – MeV photon and TeV – PeV neutrino backgrounds. This scenario can account for the MeV background without nonthermal electrons, suggesting a higher transition energy from the thermal to nonthermal Universe than expected. Transients powered by r-process nuclei ejected by neutron star mergers, emit MeV gamma-rays through nuclear decay line emission, but the predicted flux is not enough to explain the data[15]. Refs. 21,22 suggested that nonthermal electrons accelerated in the coronae of radio-quiet
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