Authors: Sylwester Kornowski
The masses and mixings of quarks have the origin in the Scale-Symmetric Theory (SST). They arise from the nuclear interactions of the source of them - it is the charge of the core of baryons (mass of the charge is 318.2955 MeV). There are the three dominating bosons: the loop with a mass of 67.54441 MeV (the neutral pions consist of two such loops), the boson that creates the Titius-Bode states for the nuclear strong-weak interactions (its mass is 750.28 MeV), and a Higgs-boson-type condensate with a mass of the bottom quark (its mass is 4190 MeV). The ratios of masses of these bosons to the mass of the source define the three mixing angles that lead to the Cabibbo-Kobayashi-Maskawa (CKM) matrix. Here we show that the SST interactions of the source of the nuclear strong interactions determine the strength of flavour-changing weak decays. Notice that contrary to SST, within the Standard Model we cannot calculate masses of quarks and the CKM-matrix mixing angles, Q(ij), from initial conditions. Within SST we obtain: Q(12) = 13.164, Q(13) = 0.212, and Q(23) = 2.357 degrees - obtained results are consistent with experimental data.
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