Neutrino signals from galactic binaries

Abstract: We analyze the possible origin of high-energy neutrinos coming from galactic sources. A model is proposed for neutrino hadroproduction in binary systems. Our results show that neutrino observatories like IceCube can establish whether TeV neutrinos and gamma rays emitted by microquasars are the decay products of pions. Such pions can be produced where the jet collides with the stellar wind of the companion star giving rise to hadronic interactions. We improve previous predictions by considering energy dependent… Show more

“…The spectral features should be detectable by an instrument like MAGIC and GLAST. Charged pion decay also leads to neutrino production as discussed in another work of the present meeting [1] (see also [27]). …”

“…For the energy dependent pion multiplicity we will follow the prescription adopted by Mannheim and Schlickeiser (1994) [21] ξ π (E p /GeV − 1.22) 1/4 , which should be valid up to 10 4 GeV, and adopt a softer root growing law for higher energies (see Christiansen et al (2006b) for details [27]). Under these assumptions, it can be shown that the maximum proton energy produced amounts to more than 50 PeV at periastron and lies below 15 PeV near apastron [1,27]. It can be derived from the simple argument that the Larmor radius of the particle should be smaller than the size of the acceleration region [22,23].…”

“…As we discuss in another work of these proceedings (see Christiansen (2006a) [1]) the study of high-energy gammarays and neutrinos is expected to provide primary hints about the origin of cosmic rays.…”

High-energy gamma-ray production in microquasars

“…The spectral features should be detectable by an instrument like MAGIC and GLAST. Charged pion decay also leads to neutrino production as discussed in another work of the present meeting [1] (see also [27]). …”

“…For the energy dependent pion multiplicity we will follow the prescription adopted by Mannheim and Schlickeiser (1994) [21] ξ π (E p /GeV − 1.22) 1/4 , which should be valid up to 10 4 GeV, and adopt a softer root growing law for higher energies (see Christiansen et al (2006b) for details [27]). Under these assumptions, it can be shown that the maximum proton energy produced amounts to more than 50 PeV at periastron and lies below 15 PeV near apastron [1,27]. It can be derived from the simple argument that the Larmor radius of the particle should be smaller than the size of the acceleration region [22,23].…”

“…As we discuss in another work of these proceedings (see Christiansen (2006a) [1]) the study of high-energy gammarays and neutrinos is expected to provide primary hints about the origin of cosmic rays.…”

High-energy gamma-ray production in microquasars