EDP Sciences : Account of the baryonic feedback effect in γ-ray measurements of intergalactic magnetic fields

Bondarenko, Kyrylo; Semikoz, Dmitri; Neronov, Andrii; Korochkin, Alexander; Boyarsky, Alexey; Sokolenko, Anastasia

doi:10.1051/0004-6361/202141595

Article
Report number	arXiv:2106.02690
Title	Account of the baryonic feedback effect in γ-ray measurements of intergalactic magnetic fields
Related title	Account of baryonic feedback effect in the $\gamma$-ray measurements of intergalactic magnetic fields
Author(s)	Bondarenko, Kyrylo (CERN ; Ecole Polytechnique, Lausanne) ; Boyarsky, Alexey (Leiden U.) ; Korochkin, Alexander (APC, Paris ; Moscow, INR ; Novosibirsk State U.) ; Neronov, Andrii (APC, Paris ; U. Geneva (main)) ; Semikoz, Dmitri (APC, Paris ; Moscow, INR ; Moscow Phys. Eng. Inst.) ; Sokolenko, Anastasia (OAW, Vienna)
Publication	2022-04-01
Imprint	2021-06-04
Number of pages	8
Note	V2: 8 pages, 7 figures, minor changes in the text. Version accepted for publication in A&A
In:	Astron. Astrophys. 660 (2022) A80
DOI	10.1051/0004-6361/202141595 (publication)
Subject category	astro-ph.HE ; Astrophysics and Astronomy ; astro-ph.CO ; Astrophysics and Astronomy
Abstract	Intergalactic magnetic fields in the voids of the large-scale structure can be probed via measurements of secondary gamma-ray emission from gamma-ray interactions with extragalactic background light. Lower bounds on the magnetic field in the voids were derived from the non-detection of this emission. It is not clear a priori what kind of magnetic field is responsible for the suppression of the secondary gamma-ray flux: a cosmological magnetic field that might be filling the voids or the field spread by galactic winds driven by star formation and active galactic nuclei. We used IllustrisTNG cosmological simulations to study the effect of magnetized galactic wind bubbles on the secondary gamma-ray flux. We show that within the IllustrisTNG model of baryonic feedback, the galactic wind bubbles typically provide energy-independent secondary flux suppression at the level of about 10%. The observed flux suppression effect has to be due to the cosmological magnetic field in the voids. This might not be the case for a special case when the primary gamma-ray source has a hard intrinsic gamma-ray spectrum that peaks in the energy range above 50 TeV. In this case, the observational data may be strongly affected by the magnetized bubble that is blown by the source host galaxy.
Copyright/License	preprint: (License: arXiv nonexclusive-distrib 1.0) publication: © 2022-2024 ESO

$Orientation of the magnetic field along the $z$ direction as a function of the magnetic field strength at redshift $0$. The blue line shows the mean value, while shaded dark and light blue regions represent areas with $68\%$ and $95\%$ of simulation volume. The dashed red line shows the seed magnetic field value $B=10^{-14}$~G.$ $Primary and secondary \gr\ spectra for the ``only voids'' magnetic field profile (only regions with $B \leq 10^{-12}$~G are taken into account). Different subplots represent different parameters of the source. Solid black and gray lines are the intrinsic and observed primary source spectra. Dashed yellow lines show the secondary \gr\ flux for a zero line of sight magnetic field. Solid red lines show the secondary \gr\ flux with a nonzero magnetic field in the voids.$ $Same as Fig.~\ref{fig:spec_only_voids}, but for the ``only bubbles'' magnetic field profiles (only regions with $B<10^{-12}$~G are taken into account). Colored solid lines indicate different LOSs.$ Show more plots

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