Ab Initio Resolution of the Black Hole Information Paradox: Asymptotic Mass Freedom and Visco-Elastic Sublimation in the KEFE Framework

We present a continuum-mechanical resolution to Black Hole Singularities and the Quantum Information Paradox using the causal Müller-Israel-Stewart (MIS) hydrodynamics of the Kinemetric-Extended Field Equations (KEFE). By shifting the ontology of the vacuum from a passive geometry to an elastoviscoplastic Zero-Point Field (ZPF) bounded by a fundamental Planck-scale Singularity Barrier (lP2), we demonstrate that infinite-density singularities are strictly forbidden. Instead, extreme gravitational collapse induces Asymptotic Mass Freedom. As the spatial manifold compresses, the resulting visco-elastic tension generates a massive negative pressure that mathematically violates the Strong Energy Condition (ρ+3P<0). This formally averts the Penrose-Hawking singularity theorems, arresting collapse to form a stable, phase-locked "Granular Vacuum Core." By evaluating the isotropic kinetic projection of the outward sublimation flux from this saturated boundary, we analytically derive the exact Bekenstein-Hawking entropy area law (S=kBA/4lP2) strictly from classical statistical mechanics. Furthermore, we demonstrate that the infinite bulk modulus of the compressed core forces it into a Topological Super-Solid. By the Landau Criterion, internal thermal scrambling is strictly frozen out, preserving a pristine topological state history. Black hole evaporation is thereby modeled as "Visco-Elastic Sublimation." Infalling matter is trapped at the outermost rigid boundary layer, naturally preventing state duplication and resolving the No-Cloning Theorem. Driven by the stochastic thermal jitter of the ambient vacuum, the macroscopic unwinding of this boundary perfectly reproduces the semi-classical thermal spectrum of Hawking radiation, while its Last-In-First-Out (LIFO) emission profile seamlessly conserves quantum unitarity without requiring abstract holographic dualities or entanglement wedges. Key Contributions: Averting Singularities: Proves that the visco-elastic tension of the KEFE vacuum violates the Strong Energy Condition, formally bypassing the Penrose-Hawking singularity theorems. Bekenstein-Hawking Entropy: Derives the exact 1/4 area-law prefactor strictly from the statistical mechanics of macroscopic boundary-layer sublimation. Resolution of the No-Cloning Paradox: Demonstrates that infalling matter phase-locks into the outermost layer of a Topological Super-Solid, preventing interior state duplication. LIFO Evaporation (The Page Curve): Replaces randomized "fast scrambling" with a deterministic Last-In-First-Out (LIFO) topological unwinding that masquerades as a featureless Planckian thermal spectrum. The KEFE Framework Suite:This manuscript is part of a comprehensive suite of papers demonstrating the universal application of the Kinemetric-Extended Field Equations (KEFE). By modeling the quantum vacuum as a causal, elastoviscoplastic continuum, the framework resolves major crises across disparate scales without dark sectors: Foundations: The Kinemetric-Extended Field Equations (KEFE): A Unified Effective Field Theory of Vacuum Rheology and Cosmological Evolution, https://doi.org/10.5281/zenodo.19333013 Cosmology: Ab Initio Resolution of the Hubble Tension: Visco-Elastic Cosmology and Conformal Degeneracy, https://doi.org/10.5281/zenodo.20254714 Galactic Astrophysics: Ab Initio Derivation of MOND and Dark Matter Profiles: Causal Decoherence and Visco-Elastic Wakes, https://doi.org/10.5281/zenodo.20254928 Quantum Gravity: Ab Initio Resolution of the Black Hole Information Paradox: Asymptotic Mass Freedom and Visco-Elastic Sublimation , https://doi.org/10.5281/zenodo.20254954