Journal of High Energy Physics (Sep 2025)
Leptoquark-mediated Dirac neutrino mass and its impact on B → Kν ν ¯ $$ B\to K\nu \overline{\nu} $$ and K → πν ν ¯ $$ K\to \pi \nu \overline{\nu} $$ decays
Abstract
Abstract Right-handed neutrinos ν R play a crucial role in flavor-changing neutral-current processes with missing energy, such as and , where Belle-II reports unexpectedly large branching fraction in B → Kν ν ¯ $$ B\to K\nu \overline{\nu} $$ decays. Assuming ν R is the partner of the active neutrino ν L in the standard model, a Dirac-type neutrino framework emerges. We investigate a scenario of radiative Dirac neutrino mass generation in a scalar leptoquark (LQ) model with a global U(1) X symmetry to suppress Majorana mass, tree-level Dirac mass, and diquark couplings. The simplest LQ realization consists of two S 1 = (3, 1, −1/3) LQs with distinct U(1) X charges. A non-Casas-Ibarra parametrization is proposed to match neutrino data with fewer model parameters. Imposing current experimental constraints from meson mixing and lepton flavor-violating processes, we find that right-handed neutrino effects can significantly enhance B → K ∗ ν ν ¯ $$ B\to {K}^{\left(\ast \right)}\nu \overline{\nu} $$ and K + → π + ν ν ¯ $$ {K}^{+}\to {\pi}^{+}\nu \overline{\nu} $$ . Additionally, the model predicts excesses in R D from B → Dτ ν ¯ $$ B\to D\tau \overline{\nu} $$ that remain within 1σ of current experimental data.
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