The Nature of γ-Ray Emission from HESS J1912+101

The Nature of γ-Ray Emission from HESS J1912+101

Abstract Since the discovery of HESS J1912+101 at teraelectronvolt energies, its nature has been extensively studied. Due to the absence of X-ray and radio counterparts, whether its γ -ray emission is produced by relativistic electrons or ions is still a matter of debate. We reanalyze its megaelectr...

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Bibliographic Details
Published in:The Astrophysical journal Vol. 953; no. 1; pp. 100 - 107
Main Authors: Li, Yuan, Liu, Siming, He, Yu
Format: Journal Article
Language:English
Published: Philadelphia The American Astronomical Society 01-08-2023
IOP Publishing
Subjects:
Astrophysics
Diffusion coefficient
Gamma emission
Gamma ray spectra
High energy astrophysics
Ion acceleration
Ions
Molecular clouds
Star clusters
Supernova
Supernova remnants
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Summary:Abstract Since the discovery of HESS J1912+101 at teraelectronvolt energies, its nature has been extensively studied. Due to the absence of X-ray and radio counterparts, whether its γ -ray emission is produced by relativistic electrons or ions is still a matter of debate. We reanalyze its megaelectronvolt to gigaelectronvolt γ -ray emission using 14 yr of Pass 8 data of the Fermi-LAT, and find that the gigaelectronvolt γ -ray emission is more extended than the teraelectronvolt shell detected by H. E. S. S. and flux above 10 GeV from the northern half is much higher than that from the southern half, where there is evident interaction between shocks and molecular clouds. As a consequence, the gigaelectronvolt spectrum of the northern half (with an index of 2.19 ± 0.12) is much harder than that in the south (with an index of 2.72 ± 0.08), and the overall gigaelectronvolt spectrum shows a concave shape, which is distinct from most γ -ray supernova remnants (SNRs). In combination with the teraelectronvolt spectrum, the overall γ -ray spectrum can be fitted with a broken power-law model for trapped ions and a low energy component due to escaping ions. The diffusion coefficient for escaping ions however needs to be proportional to the energy, implying that the low energy component may also be attributed to ions accelerated via recent shock–cloud interactions. A hadronic origin for the γ -ray emission is therefore favored and the overall emission properties are consistent with ion acceleration by SNR shocks. On the other hand, it is still undeniable that stellar cluster or PWN may have some contribution in some parts of this extended source.
Bibliography:AAS46618
High-Energy Phenomena and Fundamental Physics
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/ace344