The neutrino-nucleus reaction cross sections of 4 He and 12 C are evaluated using new shell model Hamiltonians. Branching ratios of various decay channels are calculated to evaluate the yields of Li, Be, and B produced through the -process in supernova explosions. The new cross sections enhance the yields of
We investigate neutrino oscillations in constant matter within the context of the standard three neutrino scenario. We derive an exact and simple formula for the oscillation probability applicable to all channels. In the standard parametrization, the probability for νe → νµ transition can be written in the form P (νe → νµ) = Aeµ cos δ + Beµ sin δ + Ceµ without any approximation using CP phase δ. For νµ → ντ transition, the linear term of cos 2δ is added and the probability can be written in the form P (νµ → ντ ) = Aµτ cos δ + Bµτ sin δ + Cµτ + Dµτ cos 2δ. We give the CP dependences of the probability for other channels. We show that the probability for each channel in matter has the same form with respect to δ as in vacuum. It means that matter effects just modify the coefficients A, B, C and D. We also give the exact expression of the coefficients for each channel. Furthermore, we show that our results with respect to CP dependences are reproduced from the effective mixing angles and the effective CP phase calculated by Zaglauer and Schwarzer. Through the calculation, a new identity is obtained by dividing the Naumov-Harrison-Scott identity by the Toshev identity.
Within the framework of the standard three neutrino scenario, we derive an exact and simple formula of the oscillation probability P (ν e → ν µ ) in constant matter by using a new method. From this formula, it is found that the matter effects can be separated from the pure CP violation effects. Furthermore, the oscillation probability can be written in the form, P (ν e → ν µ ) = A cos δ + B sin δ + C, in the standard parametrization without any approximation. We also demonstrate that the approximate formula in high-energy can be easily reproduced from this as an example. *
Neutrino oscillations affect light-element synthesis through the -process in supernova explosions. The 7 Li and 11 B yields produced in a supernova explosion of a 16.2 M star model increase by factors of 1.9 and 1.3 in the case of the large mixing angle solution with a normal mass hierarchy and sin 2 2 13 k 2 ; 10 À3 compared with those without the oscillations. In the case of an inverted mass hierarchy or a nonadiabatic 1-3 mixing resonance, the increment of their yields is much smaller. Neutrino oscillations raise the reaction rates of charged-current -process reactions in the region outside oxygen-rich layers. The number ratio of 7 Li/ 11 B could be a tracer of a normal mass hierarchy and a relatively large 13 , still satisfying sin 2 2 13 0:1, through future precise observations in stars having strong supernova components.
Light element synthesis in supernovae through neutrino-nucleus interactions, i.e., the v process, is affected by neutrino oscillations in the supernova environment. There is a resonance of 13-mixing in the O/C layer, which increases the rates of charged-current -process reactions in the outer He-rich layer. The yields of 7Li and 11B increase by about a factor of 1.9 and 1.3, respectively, for a normal mass hierarchy and an adiabatic 13-mixing resonance, compared to those without neutrino oscillations. In the case of an inverted mass hierarchy and a nonadiabatic 13-mixing resonance, the increase in the 7Li and 11B yields is much smaller. Observations of the 7Li/11B ratio in stars showing signs of supernova enrichment could thus provide a unique test of neutrino oscillations and constrain their parameters and the mass hierarchy.
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