Photon–Corridor Δf Mechanism (v2.2): Quantitative Hg Afterglow Beating Model and Operational Detuning Tests

This manuscript presents a focused upgrade of the original msf: 45712 photon–lattice Δf mechanism into a measurement-ready, solid-state/atomic emission framework. In this document, “Mercury” refers only to the chemical element Hg (not the planet). USP Field Theory models photon–matter interaction as localized corridor coupling and tension rebalancing governed by a frequency mismatch parameter Δf. The central contribution of this version is a quantitative, falsifiable prediction for Hg afterglow: after excitation is reduced or removed, delayed emission can include a short-lived decaying beating component when excitation is distributed across two (or more) nearby corridor-supported mode families. The document provides: • Operational definitions for detuning (Δf and the dimensionless detuning ratio χ = Δf / fcorr) • A time-series fit model for afterglow intensity I (t) containing both smooth relaxation and a decaying beating residual • A toy coupled-mode estimate that predicts how the beating amplitude ratio (B/A) scales with detuning χ • A compact protocol sketch for data fitting and model comparison (single exponential vs beating-augmented model) • Clear, testable predictions and explicit falsification paths This work preserves causal consistency (no superluminal signaling) and does not claim to alter established quantum-optical observables such as spectral lines or measured lifetimes. It is written to stand alone as a practical emission-note document suitable for detuning-sweep style analysis.