What question did this study set out to answer?

To reformulate the weak nuclear interaction within the Superstring–Fabric Spacetime framework and explore its geometric foundations.

February 8, 2026Open Access

Superstring–Fabric Spacetime (SFS): Geometric Origin of the Weak Nuclear Force

Key Points

To reformulate the weak nuclear interaction within the Superstring–Fabric Spacetime framework and explore its geometric foundations.
Developed an effective elastic Lagrangian for the spacetime fabric.
Examined compressional and rotational distortions affecting particle interactions.
Derived a unified geometric vector field incorporating curvature and torsion components.
Showed the relation of the geometric field to conserved particle–wave currents in low-energy scenarios.
Identified weak interactions as dynamic couplings of geometric deformation modes.
Demonstrated parity violation from the axial nature of torsional distortions.
Reproduced features of Fermi's theory of beta decay through geometrical principles.
Provided a geometric explanation for weak interaction characteristics without relying on symmetry breaking.

Abstract

AbstractIn this work, the weak nuclear interaction is reformulated within the Superstring–Fabric Spacetime (SFS) framework, where spacetime is modeled as a continuous elastic medium composed of interconnected fundamental strings. Elementary particles are interpreted as localized wave excitations of this fabric, while fundamental interactions arise from specific geometric deformation modes. Starting from an effective elastic Lagrangian for the spacetime fabric, we show that compressional (curvature) and rotational (torsional) distortions correspond to independent propagating degrees of freedom. Weak interaction processes are identified with regimes in which these modes become dynamically coupled through topological rearrangements of particle–wave configurations. A unified geometric vector field Wμ, constructed from curvature and torsion components, is derived and shown to satisfy a Proca–type equation with an effective mass determined by the torsional stiffness of the fabric. Coupling this geometric field to conserved particle–wave currents yields, in the low–energy limit, an effective four–current interaction identical in form to Fermi’s theory of beta decay. Parity violation emerges naturally from the axial character of torsional distortions, providing a geometric explanation of the handedness observed in weak processes. The framework reproduces the short interaction range, universality of the Fermi constant, and qualitative features of the electroweak sector without invoking spontaneous symmetry breaking as a fundamental mechanism. These results suggest that the weak interaction may be understood as an emergent manifestation of spacetime fabric dynamics rather than as a purely internal gauge interaction. Related Works (Superstring–Fabric Spacetime (SFS) Program): Core SFS model formulation (SFS Model):https://doi.org/10.5281/zenodo.17727233 Extended quantum–geometric framework (SFS Model):https://doi.org/10.5281/zenodo.17864031 Geometric origin of electromagnetism (SFS Model):https://doi.org/10.5281/zenodo.18182324 Geometric Origin of the Strong Nuclear Force (SFS Model):https://doi.org/10.5281/zenodo.18498802

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Karrar Shuhaib (Fri,) studied this question.

synapsesocial.com/papers/6988290a0fc35cd7a88491bb https://doi.org/https://doi.org/10.5281/zenodo.18503483

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