A minimization theorem for the Koide ratio and its Standard Model calibration

Abstract

The charged-lepton Koide relation remains a striking empirical regularity in Standard-Model flavor data. We prove that for any positive mass set with Koide ratio Q0, the one-particle extension Q(m1,…,mN,x) has a unique global minimum Qmin=Q0/(1+Q0) at m*=[(Σi mi)/(Σi mi)]2. This exact kinematic result defines a unique extension benchmark. For the measured charged leptons it gives m* = 1.255\,34(16)\,GeV and Q4,exp = 0.399\,997\,8(43); in the ideal Koide limit QK=2/3, the corresponding minimum is exactly 2/5. In the effective-participant language Neff 1/Q, the optimal one-particle extension increases Neff by one, while the equal-k multiplet extension increases it by k. The one-particle Neff profile is exactly Lorentzian in a dimensionless share-mismatch coordinate u, which we interpret kinematically rather than dynamically. Using charged-lepton pole masses with the PDG~2024 own-scale MS charm mass gives Q(e,μ,τ,c)=0.400\,002\,5(64), i.e. 11.7\,ppm above the measured-input benchmark and 6.2\,ppm above 2/5. This intentionally mixed-definition comparison is treated only as a phenomenological coincidence. To calibrate it within a stated benchmark class, we perform an exhaustive common-scale scan over non-neutrino Standard Model 2-body and 3-body seeds with one added mass. The charged-lepton-plus-charm continuation ranks 33/12,720 in the raw trial set, 24/2,640 after collapsing repeated scale realizations, and 6/756 within the fermion-only collapsed subset. We present the charm case as an empirically calibrated example of the theorem, not as a dynamical flavor model.