We present ATPEW (ALdon Theory of Primordial Energy Wave), an exploratory conceptual framework in which all physical objects are topological vortex configurations of a single complex scalar field Ψ = ÷exp(iθ), governed by the Lagrangian: ℒ = α(∂μÃ)² + βò(∂μθ)² − λÃ⁻² − μ²Ã² In this framework, a black hole is a spherically stratified structure — two concentric spheres of radii rcore and rph delimiting five functionally distinct zones — whose internal phase field carries a closed toroidal winding of number k. The hollow core of this structure, a wave vacuum where no stable frequency mode can form, lies beneath the Schwarzschild horizon when the winding number k exceeds the topological closure threshold kseuil = rs·√(2μ²/β). The event horizon is not a mathematical surface but a waveguide condition: modes with angular frequency ω > rs. The framework is confronted with two independent observational datasets. Analysis of 91,846 EHT visibility measurements of M87* (2018, 3 days, 4 frequency bands, 213–229 GHz, HOPS and CASA pipelines) yields a photon ring diameter of 41.1 μas, a +3.6% excess over the GR prediction of 39.7 μas, constraining β/(μ²·rs²) ≈ 0.056 (k=5). Analysis of raw LIGO GW150914 strain data (H1 detector, 4096 Hz, GWF binary format, zlib extraction) yields fQNM = 249 ± 7 Hz consistent with GR for Mfinal ≈ 68 M☉, with correction δf/f 3.6×10⁵⁷ (black hole formation). Three qualitatively distinct merger regimes are predicted depending on phase alignment. Hawking evaporation is reinterpreted as spontaneous quantum unraveling of the spiral tail, yielding TATPEW ∝ 1/M with the correct order of magnitude. Ten observational predictions distinguishable from GR are identified, testable by next-generation EHT, future LIGO catalogs, and next-generation gravitational wave detectors. Three explicit open mathematical problems are listed.
Michel ALdon (Tue,) studied this question.