2014
DOI: 10.1051/epjconf/20147100044
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Beta Decay and the Cosmic Neutrino Background

Abstract: Abstract. In 1964 Penzias and Wilson detected the Cosmic Microwave Background (CMB). Its spectrum follows Planck's black body radiation formula and shows a remarkable constant temperature of T 0γ ≈ 2.7 K independent of the direction. The present photon density is about 370 photons per cm 3 . The size of the hot spots, which deviates only in the fifth decimal of the temperature from the average value, tells us, that the universe is flat. About 380 000 years after the Big Bang at a temperature of T 0γ = 3000 K a… Show more

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Cited by 24 publications
(22 citation statements)
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“…For m ν = 0.3 (0.15) eV, the rate is 7.5 (7.5), 23 (10), and 23 (12), respectively, with FD, NFWhalo and MWnow distribution [11]. A calculation by Faessler et al [29] finds that the NCB rate per year for the 3 H target (50 μg) to be used for the KATRIN experiment [30] is 4.2×10 −6 n ν / < n ν > which is consistent with the result by Cocco et al above for the FD distribution with n ν / < n ν >= 1. A similar calculation for 760 g of 187 Re to be used for the MARE calorimetric experiment [31] finds the event rate per year 6.7×10 −8 n ν / < n ν >, which is too small for a likely value for n ν / < n ν >.…”
Section: Neutrino Capture By Cνb-decaying Nucleimentioning
confidence: 96%
“…For m ν = 0.3 (0.15) eV, the rate is 7.5 (7.5), 23 (10), and 23 (12), respectively, with FD, NFWhalo and MWnow distribution [11]. A calculation by Faessler et al [29] finds that the NCB rate per year for the 3 H target (50 μg) to be used for the KATRIN experiment [30] is 4.2×10 −6 n ν / < n ν > which is consistent with the result by Cocco et al above for the FD distribution with n ν / < n ν >= 1. A similar calculation for 760 g of 187 Re to be used for the MARE calorimetric experiment [31] finds the event rate per year 6.7×10 −8 n ν / < n ν >, which is too small for a likely value for n ν / < n ν >.…”
Section: Neutrino Capture By Cνb-decaying Nucleimentioning
confidence: 96%
“…The transformation to an integral over the energy yields the factor in front of the third term, which can be deduced from ref. (10). Different neutrino mass eigenstates |i > are mixed into the electron neutrino flavor states by U 2 e,i .…”
Section: The Capture Processmentioning
confidence: 99%
“…E f ′ , E f ′ ,p ′ and E f ′ ,p ′ ;q ′ >0 are the 1-hole, the 2-hole shake-up and the 2-hole shake-off excitation energies in Dysprosium (see refs. [7] and [10]). Γ f ′ , Γ f ′ ,p ′ and Γ f ′ ,p ′ ;q ′ >0 are the widths of the one-and two-hole states and the two-hole states with shake-off in Dysprosium [15,16,18].…”
Section: The Capture Processmentioning
confidence: 99%
“…The standard cosmology of the CνB has been reminded in [115] having in view the use of the Karlsruhe Tritium Neutrino (KATRIN) spectrometer [116][117][118] devoted to the inelastic reaction between an electron neutrino and a 3 H nucleus: ν + 3 H → 3 He + e − . Another experimental project using a tritium target is PTOLEMY (Princeton Tritium Observatory for Light, Early Universe Massive Neutrino Yield) [119,120].…”
Section: The Detection Of Cosmic Neutrino Backgroundmentioning
confidence: 99%