B-L model with A4× Z3× Z4 symmetry for 3+1 active-sterile neutrino mixing

Abstract

We construct a multiscalar and nonrenormalizable B-L model with A4× Z3× Z4 flavor symmetry which successfully explains the recent 3+1 active-sterile neutrino data. The tiny neutrino mass the mass hierarchy are obtained by the type-I seesaw mechanism. The hierarchy of the lepton masses is satisfied by a factor of vH (vl)2 10-4\, GeV of the electron mass compared to the muon and tau masses of the order of vH vl 10-1\, GeV. The recent 3+1 active-sterile neutrino mixings are predicted to be 0.015 ≤|Ue 4|2≤ 0.045, 0.004 ≤|Uμ 4|2≤ 0.012, 0.004 ≤|Uτ 4|2≤ 0.014 for normal hierarchy and 0.020≤|Ue 4|2≤ 0.045, 0.008 ≤|Uμ 4|2≤ 0.018, 0.008≤|Uτ 4|2≤ 0.022 for inverted hierarchy. Sterile neutrino masses are predicted to be 0.7 ms \, (eV) 3.16 for normal hierarchy and 2.6 ms \, (eV) 7.1 for inverted hierarchy. For three neutrino scheme the model predicts 0.3401 ≤ 2θ12≤ 0.3415, \, 0.460 ≤ 2θ23≤ 0.540,\, -0.60 ≤ δCP≤ -0.20 for normal hierarchy and 0.3402 ≤ 2θ12≤ 0.3416,\, 0.434≤2θ23≤ 0.610,\, -0.95 ≤ δCP≤ -0.60 for inverted hierarchy. The effective neutrino masses are predicted to be 35.70 ≤ mee [meV] ≤ 36.50 in 3+1 scheme and 3.65 ≤ m(3)ee [meV] ≤ 4.10 in three neutrino scheme for NH while 160.0 ≤ mee [meV] ≤ 168.0 in 3+1 scheme and 47.80 ≤ m(3)ee [meV] ≤ 48.70 in three neutrino scheme for for IH which are all in agreement with the recent experimental data.