Gauge couplings of the Standard Model in the octonionic framework: a broken-phase mechanism for αs/αem=16

Abstract

We present a consolidated gauge-sector account of the octonionic programme, starting from the trace-dynamics Lagrangian and ending with closed-form expressions for the strong and electromagnetic couplings, together with a brief review of the weak mixing angle. The main new step is a broken-phase support mechanism on the real octonionic ladder space H6 which, under a specific support hypothesis, gives equation αsαem=16 equation from a common visible Yang--Mills coupling. We then combine this relation with the 2022 Eur. Phys. J. Plus seed [1] equation A:=\![q0\!(q0-38)], q0=13, equation to obtain equation αsth(MZ)=964\![23\!(13-38)]=0.11675418, equation equation αemth(0)=91024\![23\!(13-38)]=0.00729713629. equation The electromagnetic formula is algebraically the same as in the earlier paper [1], but its factor 1/16 is now attached to an explicit broken-phase gauge normalization rather than to a length-identification step. A key conceptual point is that the seed is tied to the minimal visible charge quantum q0=1/3, not to a specific particle species: the electron, whose charge is 1=3q0, enters later through the electromagnetic charge trace kem=8/3. We also review the earlier spinorial derivation of the weak mixing angle [2], which yields 2θWth=0.24969776, and assess it separately. The strong and electromagnetic results are numerically close to experiment; the weak-angle comparison is substantially less successful.