Non-thermal emission in M31 and M33

Spiral galaxies M31 and M33 are Fermi/LAT-detected gamma-ray sources. We model the broadband non-thermal (NT) emission of the central region of M31 (R < 5.5 kpc) and of the disk of M33 (R ~ 9 kpc). For either galaxy, we self-consistently model the broadband SED of the diffuse NT emission based on...

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Bibliographic Details
Published in:arXiv.org 2024-05
Main Authors: Persic, Massimo, Rephaeli, Yoel, Rando, Riccardo
Format: Article
Language:English
Subjects:
Bremsstrahlung
Broadband
Elastic scattering
Electrons
Galaxy distribution
Gamma emission
Gamma ray astronomy
Gamma ray sources
Gamma rays
Hydrogen
Magellanic clouds
Pions
Protons
Pulsars
Radio emission
Relativistic effects
Spiral galaxies
Thermal emission
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Summary:Spiral galaxies M31 and M33 are Fermi/LAT-detected gamma-ray sources. We model the broadband non-thermal (NT) emission of the central region of M31 (R < 5.5 kpc) and of the disk of M33 (R ~ 9 kpc). For either galaxy, we self-consistently model the broadband SED of the diffuse NT emission based on published radio and gamma-ray data. All relevant radiative processes involving relativistic and thermal electrons (synchrotron, Compton scattering, bremsstrahlung, and free-free emission and absorption), along with relativistic protons (neutral-pion decay following interaction with thermal protons), are considered, using exact emissivity formulae. We also use the Fermi/LAT validated gamma-ray emissivities for pulsars. We find that, in both sources, the radio emission is composed of primary and secondary electron synchrotron and thermal bremsstrahlung. The M33 gamma-ray emission appears to be mainly hadronic, similar to the Magellanic Clouds (Persic & Rephaeli 2022). In contrast, we find suggestions of a more complex situation in the central region of M31, whose emission could be a mix of pulsar emission and hadronic emission, with the latter possibly originating from both the disk and the vicinity of the nuclear black hole. The alternative modelling of the spectra of M31 and M33 is motivated by the different hydrogen distribution in the two galaxies: the hydrogen deficiency in the central region of M31 partially unveils emissions from the nuclear BH and the pulsar population in the bulge and inner disk. If this were to be the case in M33 as well, these emissions would be outshined by diffuse pionic emission originating within the flat central-peak gas distribution in M33.
ISSN:2331-8422