Quasi-energy-independent solar neutrino transitions

Current solar, atmospheric, and reactor neutrino data still allow oscillation scenarios where the squared mass differences are all close to 10(-3) eV(2), rather than being hierarchically separated. For solar neutrinos, this situation (realized in the upper part of the so-called large-mixing angle solution) implies adiabatic transitions which depend weakly on the neutrino energy and on the matter density, as well as on the atmospheric squared mass difference. In such a regime of quasi-energy-independent (QEI) transitions, intermediate between the more familiar Mikheyev-Smirnov-Wolfenstein (MSW) and energy independent (EI) regimes, we first perform analytical calculations of the solar nu(e) survival probability at first order in the matter density, beyond the usual hierarchical approximations. We then provide accurate, generalized expressions for the solar neutrino mixing angles in matter, which reduce to those valid in the MSW, QEI and EI regimes in appropriate limits. Finally, a representative QEI scenario is discussed in some detail.