Building on the structural constraint identified in ICC XVI, we investigate whether a non-vanishing geometric phase ansatz can restore quantitative predictivity for the CP violating phase δCP in the PMNS matrix. We propose a modified functional form γi ∝ arctan( mi/m0) with m0 ∼ 10−2 eV, which remains O(1) for m → 0 while preserving the √mscaling for heavy states. Monte Carlo simulations yield δCP = 1.00π±0.56π, with the central value shifted closer to the T2K/NOvA best fit compared to ICC XVI (1.04π → 1.00π). However, the distribu tion remains broad due to the nonlinear unitary projection V = polar(M), which amplifies residual stochastic fluctuations even when geometric phase differences are O(0.1–0.4π). This constitutes a refined structural constraint: sharp predictions for δCP require not only non-vanishing geometric phases but also additional dynamical correlations that sup press the sensitivity of the unitarization map to stochastic noise. The predicted distribution is falsifiable: future measurements constraining σδ ≲ 0.2π would require physics beyond geo metric phases alone. This work establishes the minimal conditions for quantitative precision and identifies dynamical correlations as the next necessary ingredient.
Alik Gimranov (Thu,) studied this question.
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