The neutrinophilic two Higgs doublet model is one of the simplest models to
explain the origin of tiny Dirac neutrino masses. This model introduces a new
Higgs doublet with eV scale VEV to naturally generate the tiny neutrino masses.
Depending on the same Yukawa coupling, the neutrino oscillation patterns can be
probed with the dilepton signature from the decay of charged scalar H±.
For example, the normal hierarchy predicts BR(H+→e+ν)≪ BR(H+→μ+ν)≈ BR(H+→τ+ν)≃0.5 when the lightest neutrino
mass is below 0.01 eV, while the inverted hierarchy predicts BR(H+→e+ν)/2≃ BR(H+→μ+ν)≃ BR(H+→τ+ν)≃0.25.
By precise measurement of BR(H+→ℓ+ν), we are hopefully to probe the
lightest neutrino mass and the atmospheric mixing angle θ23​. Through
the detailed simulation of the dilepton signature and corresponding
backgrounds, we find that the 3 TeV CLIC could discover MH+​≲1220
GeV for NH and MH+​≲1280 GeV for IH. Meanwhile, the future 100 TeV
FCC-hh collider could probe MH+​≲1810 GeV for NH and
MH+​≲2060 GeV for IH.Comment: 18 pages, 9 figure