Lorentz-FitzGerald Contraction as the Unique Closure Condition for Moving Spherical-Harmonic Cavities

Abstract

We prove that the Lorentz--FitzGerald contraction is the unique deformation of a resonant cavity moving through a mechanical wave medium that preserves spherical-harmonic phase closure. For a cavity moving at speed v = β c through a medium supporting nondispersive wave propagation at speed c, the round-trip phase of an internal ray at angle θ to the motion depends on the boundary radius r(θ) according to (θ) = 2k\,r(θ)1-β22θ/(1-β2). Requiring (θ) to be independent of θ -- the necessary condition for retaining a spherical-harmonic eigenstructure -- uniquely fixes the Lorentzian aspect ratio \[ aa = 1γ = 1-β2. \] Substituting this unique boundary into the round-trip time yields the resonant period dilation T = γ T0, without additional assumptions. Both results -- contraction and dilation -- follow from a single mechanical constraint: preservation of eigenstructure under motion. This is the missing uniqueness theorem of the constructive relativity program initiated by FitzGerald, Lorentz, and Heaviside: the proof that Lorentzian kinematics are not merely consistent with, but uniquely required by, phase closure in a mechanical wave medium.