Tejinder P. Singh’s electroweak-scale Koide parameter Kₜh = 0. 66916 departs from the PUH low-energy value QPDG = 0. 66666051 by Δ +0. 002499. We test whether renormalization group running can bridge this gap. Three mechanisms are tested numerically: dielectric scaling of the Z3 breaking parameter ε; standard QED logarithmic mass running; and geometric differential running with anomalous dimensions fixed by E8 lattice weights. All three fail — producing |ΔQ| less than 10^-4, three orders of magnitude below the required shift — and standard QED running moves Q in the wrong direction. The conclusion is that Singh’s Kₜh is not a renormalization scale effect on pole masses. It is an algebraic quantity from Jordan algebra eigenvalues before mass identification. Theorem 171 establishes: (1) PUH’s Z3 breaking ε = -9. 62×10^-6 and Singh’s triality breaking are different geometric objects at different algebraic levels; (2) the correct bridge is a geometric map from Jordan eigenvalues to E8 lattice mode frequencies, not RG running; (3) the derivation of ΔQ = 0. 002499 from E8 geometry in closed form is identified as the key open calculation connecting PUH to Singh’s framework.
Brian Martell (Mon,) studied this question.