This paper presents version 10 of the Emergent Resonant Brane (ERB) model, which defines elementary particles as resonant oscillation nodes within an elastic vacuum brane (tension ₀ 0. 1099). The central element of this framework is the identification of a fundamental 7. 02% geometric asymmetry ("gap") between the up- and down-quark sectors, acting as the mechanical driver for global phase synchronization. We mathematically derive that the system enforces a topological phase-lock at = 2, enabling the definition of a stable 4-pi fermion state. We demonstrate the existence of an algebraic coupling between the dispersion exponent of the whip-core and the mass-scaling exponent in the form of = = 2. This relation allows for the direct calculation of the fine-structure constant ₄₌ as a mechanical amplitude ratio with 99. 9% accuracy relative to experimental values. Furthermore, the observed hierarchy of the six quark masses—including the extreme scaling factor of 8 10⁴ between the up and top quarks—is attributed to an exponential r^2 dependence. While the topological structure is strictly dictated by 2, we identify a remaining numerical divergence as the effect of a transducer operator T. This operator mediates between the "naked" Bessel geometry and the effective inertia of the brane. The consistency of the model is validated through a simultaneous fit of both isospin sectors, where the "honest limit" of the theory is discussed as a necessary consequence of vacuum warping effects.
Daniel Speckmann (Fri,) studied this question.
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