Electron–Positron Annihilation as Coherent Resonance Cancellation A Corridor-Based Interpretation of Collider Signatures in USP Field Theory

This document presents a corridor-based interpretation of electron–positron annihilation within the framework of USP Field Theory. In this view, electrons and positrons are modeled as stationary oscillatory structures stabilized by resonance corridors. When opposite-phase corridors overlap in collider interactions, coherent cancellation can occur if the combined detuning falls within a finite locking linewidth. The annihilation process is therefore interpreted not as the disappearance of matter but as the release of stored oscillatory energy from a confined stationary configuration into propagating photon modes. The standard two-photon annihilation channel is explained as the natural unwinding of the corridor’s spin-tension structure while preserving conservation of energy and momentum. To connect the theoretical framework with collider phenomenology, a phenomenological detuning proxy linking center-of-mass energy and interaction scale is introduced. The model also proposes a scaling relation for the effective cancellation linewidth that governs corridor locking. Observable diagnostics are proposed for experimental comparison with standard collider predictions. These include angular residuals in photon emission distributions, polarization correlations, and likelihood-based model comparison. A minimal Monte Carlo procedure is outlined to demonstrate how the linewidth parameter could be extracted from collider data. The purpose of the document is not to replace standard quantum electrodynamics descriptions of annihilation outcomes, but to propose an alternative mechanistic interpretation that may produce small, testable residual signatures in high-statistics lepton collider datasets.