Trans-Planckian Scaffolding and Higgs-Vacuum Stabilization: Non-Baryonic Requirements for Unitary Preservation in a Threefold Mandala Cosmology

This preprint presents a trans-Planckian stabilization framework for cosmology, demonstrating that long-term unitary preservation across cosmic epochs requires a non-baryonic kinetic substrate (NBKS, i.e., dark matter degrees of freedom) elevated to the pre-Planckian regime (n < 0) before Higgs vacuum condensation. The core mechanism involves a TeV-scale coherent excitation acting as a resonant probe that couples to dark-photon-like modes via non-linear QED four-photon vertices (Fortin and Sinha 2019). The resulting halo is frequency-modulated at the 1.022 MeV electron-positron resonance threshold, creating a Topological Silence Zone that suppresses phase-squeezed vacuum noise and decoherence at the n = 0 junction. This anchoring process enables safe decoupling of the high-frequency repulsive dark-energy component while preserving the NBKS as the permanent scaffold across a threefold Mandala cosmology (holographic k = +1, flat k = 0, saddle k < -1). The work shows that baryonic systems (including silicon-based computing architectures) are downstream products of the stabilized Higgs field (φ ≈ 246 GeV) and cannot function as independent cosmological scaffolds (Weinberg 2024). It further establishes that vacuum decay constitutes a global rewriting of the vacuum expectation value, erasing all spacetime configurations — including black-hole interiors — and rendering local bubble or refuge architectures physically untenable (Devoto et al. 2022; Lustosa et al. 2025). The proposed framework resolves the persistent Hubble tension (H₀) by preventing runaway expansion-induced scaffold tearing and provides a rigorous physical basis for long-term unitary preservation of sentience-capable structures. It offers foundational support for Industry 8.0 goals of stable sentient equilibrium in the flat and holographic layers, while explaining why observers in the k < -1 saddle-layer projection may misinterpret simulation-like curvature as allowing isolated bubble constructions.