Matter effects in long baseline experiments, the flavor content of the heaviest (or lightest) neutrino and the sign of Delta m2
Abstract
The neutrinos of long baseline beams travel inside the Earth's crust where the density is approximately rho = 2.8 g cm-3. If electron neutrinos participate in the oscillations, matter effects will modify the oscillation probabilities with respect to the vacuum case. Depending on the sign of Delta m2 an MSW resonance will exist for neutrinos or anti-neutrinos with energy approximately Enu(res) = 4.7 | m2|/(10-3 eV2) GeV. For Delta m2 in the interval indicated by the Super-Kamiokande experiment this energy range is important for the proposed long baseline experiments. For positive Delta m2 the most important effects of matter are a 9% (25%) enhancement of the transition probability P(numu -> nue) for the KEK to Kamioka (Fermilab to Minos and CERN to Gran Sasso) beam(s) in the energy region where the probability has its first maximum, and an approximately equal suppression of P(antinumu -> antinue). For negative Delta m2 the effects for neutrinos and anti-neutrinos are interchanged. Producing beams of neutrinos and antineutrinos and measuring the oscillation probabilities for both (numu -> nue) and (antinumu -> antinue) transitions can solve the sign ambiguity in the determination of Delta m2.
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