Neutrino signatures of the origins of cosmic rays

Nuclear physics. B, Proceedings, supplements Pub Date : 2014-11-01 DOI:10.1016/j.nuclphysbps.2014.10.031

Karl Mannheim

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引用次数: 4

Abstract

The intensity of extraterrestrial neutrinos discovered by IceCube [M. G. Aartsen et al. (IceCube Collaboration), Science 342 (2013) 1242856] is in reasonable agreement with predictions of neutrinos from the jets of active galactic nuclei due to pion production by accelerated protons [K. Mannheim, Astropart. Phys. 3 (1995) 295]. The observed deficit of Glashow-resonance events at 6.3 PeV could result from the suppression of events with energies larger than PeV due to the presence of a strong “big blue bump” radiation field in flat-spectrum radio quasars. The total neutrino spectrum could exhibit a two-component structure in which the sub-PeV component is dominated by the jets from AGN with high accretion rates and another component peaking at EeV energies due to those with low accretion rates. Each component of the neutrino spectrum should carry the energy flux that corresponds to its relative contribution to the extragalactic gamma ray background. The arrival directions should correlate with known sources, and a simple test shows that the PeV events can indeed be explained by known blazars with prominent radio jets. If a Galactic component of cosmic rays with energies per nucleon above knee energies exists, as air shower array data seem to indicate, the neutrinos due to pion production from these sources are also detectable, pinpointing them an energies where gamma-ray observations are not yet possible.

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宇宙射线起源的中微子特征

冰立方发现的地外中微子强度[M]。G. Aartsen et al. (IceCube Collaboration)， Science 342(2013) 1242856]与加速质子产生介子导致的活动星系核喷流产生中微子的预测基本一致[K]。Astropart曼海姆。物理学3(1995)295]。观测到的6.3 PeV的格拉斯哥共振事件的缺陷可能是由于在平谱射电类星体中存在强大的“蓝色大包”辐射场而抑制了能量大于PeV的事件。总中微子谱可能呈现双组分结构，其中亚pev组分主要来自具有高吸积率的AGN喷流，另一个组分由于吸积率低而在EeV能量处达到峰值。中微子光谱的每个分量都应该携带能量通量，对应于它对河外伽马射线背景的相对贡献。到达的方向应该与已知的来源相关，一个简单的测试表明，PeV事件确实可以用已知的具有显著射电喷流的耀变体来解释。如果宇宙射线的银河系成分存在，其每核子的能量高于膝盖能量，正如空气阵雨阵列的数据所显示的那样，由这些来源产生的介子产生的中微子也可以被探测到，精确地指出它们的能量是伽马射线观测尚不可能的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Nuclear physics. B, Proceedings, supplements

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