Abstract The Non-Hermitian Algebraic Gravity framework (MTN-G) derives spacetime geometry as a thermodynamic phase transition from a Type III₁ von Neumann algebraic substrate. At the cosmic Exceptional Point (EPᵈ), eigenvector coalescence archives pre-geometric modular coherence into the Sparse-Reservoir Substrate Memory network, leaving a spectral scar: a k²-suppressed primordial power spectrum at wavenumbers k 2.5σ) and H2 (E/B parity asymmetry > 2σ) both pass from published Planck 2018 VII results (3.5σ and 2.1σ respectively; foreground contamination bounded to 0 at ℓ = 2–5), both testable on existing Planck data once the island direction n̂₀ is determined. The MTN-G core framework (D1–D6) is not falsified. The TL conjecture is INCONCLUSIVE pending the definitive MultiNest analysis specified in Section VIII and Appendix A. Key Words: MTN-G / Non-Hermitian Algebraic Gravity · Temporal Layering · Exceptional Point coalescence · Type III₁ von Neumann algebra · emergent spacetime · primordial power spectrum · k²-suppression · CMB low-ℓ anomalies · quadrupole suppression · E/B parity asymmetry · directional power spectrum · spherical-cap patch scan · Planck 2018 PR3 · Bayesian model comparison · MultiNest · look-elsewhere correction · Poisson channel density · SRSM network · T-E cross-correlation · E-mode angular skewness · pre-registration · falsifiability
José Caetano de Mattos (Thu,) studied this question.