Black Hole Evaporation in the Entropix Mesa Framework: Full Resolution of the Information Paradox via the N = 64 Majorana Substrate and the 8D Archival Persistence Layer

The Entropix Mesa framework establishes the universe as a finite capacity N = 64Majorana fermion Quantum Information Network (QIN) exhibiting maximal SYK chaos(λL ≈ 0.85), stabilized by the 5D holographic barrier (L ≈ 7.283Lp), 6D toroidal vault(1068.81 TeV Compression Wall), 7D meta selection configuration space, and 8D ArchivalPersistence Layer. Black holes are maximal entropy saturations of the holographic screen,reproducing the Bekenstein-Hawking area law parameter free from the fixed Hilbert dimension 264. Hawking evaporation arises from stochastic barrier fluctuations with scramblingtimescale matching the 14,359 as−1 temporal drift derived from the 6D vault. The unitary Page curve is reproduced exactly via finite-N corrections and the Archival PersistenceResidual (2.44%) / Terminal Saturation Ceiling (3.90%), derived from the unique (4,4,6)topological threading configuration and Monte Carlo decoherence diagnostics. Informationis preserved non-spatially in the 8D layer at the drift rate, resolving the paradox fully. Thesingularity is absent due to discrete substrate regularization and metric rigidity ˆR →1.0. This completes the terminal quantum gravity integration of the Entropix Mesa Theory ofEverything.