2021
DOI: 10.1093/mnras/stab1804
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High-energy neutrino production in clusters of galaxies

Abstract: Clusters of galaxies can potentially produce cosmic rays (CRs) up to very-high energies via large-scale shocks and turbulent acceleration. Due to their unique magnetic-field configuration, CRs with energy ≤1017 eV can be trapped within these structures over cosmological time scales, and generate secondary particles, including neutrinos and gamma rays, through interactions with the background gas and photons. In this work we compute the contribution from clusters of galaxies to the diffuse neutrino background. … Show more

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Cited by 23 publications
(55 citation statements)
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“…We see that the neutrino intensity for the secondarydominant model with α = 2.0 (left panel, thin solid) becomes 3 − 30% to the observed one, which is consistent with previous results on the typical accretion shock scenario (Murase et al 2008;Fang & Olinto 2016;Hussain et al 2021). Note that the neutrino luminosity function has not been considered in our estimate.…”
Section: Contributions To Cumulative Neutrino and Gamma-ray Backgroundssupporting
confidence: 90%
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“…We see that the neutrino intensity for the secondarydominant model with α = 2.0 (left panel, thin solid) becomes 3 − 30% to the observed one, which is consistent with previous results on the typical accretion shock scenario (Murase et al 2008;Fang & Olinto 2016;Hussain et al 2021). Note that the neutrino luminosity function has not been considered in our estimate.…”
Section: Contributions To Cumulative Neutrino and Gamma-ray Backgroundssupporting
confidence: 90%
“…By including the cluster mass function and its redshift evolution as well as the CR distribution, the intensities can be further enhanced by a factor of ∼ O(1) − O(10), in which ∼ 100% of the IceCube intensity can be explained. For example, if CRPs are mainly injected from internal sources like AGNs, the redshift evolution of the source density can be as large as ξ z ∼ 3, instead of ξ z ∼ 1 (e.g., Fang & Murase 2018;Hussain et al 2021). The neutrino luminosity scales with L ν ∝ M 500 (that is different from the accretion shock scenario), the background intensity mainly originates from more clusters lighter than Coma .…”
Section: Contributions To Cumulative Neutrino and Gamma-ray Backgroundsmentioning
confidence: 99%
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“…They can be considered as "closed boxes" that retain all their gaseous matter. Most of the cosmic rays produced in clusters of galaxies remain confined within the cluster and produce high-energy gamma rays and neutrinos [709,710] by interactions with the intracluster baryonic gas. A multi-messenger approach would provide insights to probe if galaxy clusters are sources of UHECRs.…”
Section: Galaxy Clustersmentioning
confidence: 99%