We investigate whether geometric phases in the Information-Copying Cosmology framework can yield quantitative predictions for the CP-violating phase δCP in the PMNS matrix. Building on the topological structure π1(M) ∼ = Z established in ICC XIII, we test the minimal ansatz θi = θ0 +γgeom i +εi with γi ∝ mi/mτ. Monte Carlo simulations yield a broad distribution δCP = 1.04π ±0.63π, with only 11% of realizations within the current T2K/NOvA 1σ range. We trace this to the extreme mass hierarchy mν/mτ ∼ 10−11, which suppresses geometric phases for neutrinos to γν ∼ 10−6π, leaving phase differences dominated by the charged lepton sector. This constitutes a structural constraint: sharp predictions for δCP require either (i) a geometric phase functional form that remains O(1) for m → 0, (ii) sector-dependent reference scales, or (iii) additional dynamical correlations. The predicted broad distribution is falsifiable: future measurements constraining σδ ≲ 0.2π would require extensions beyond the minimal geometric ansatz. This work establishes the geometric foundation for leptonic CP violation and defines the minimal conditions for quantitative precision.
Alik Gimranov (Thu,) studied this question.
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